Stability and Kinetic Properties of a Magnetic Immobilized alpha-Amylase K

The properties of α-amylase K immobilized on hydrous titanium(IV)oxide coated magnetic iron oxide are reported and compared with the previously reported properties of the soluble form of the enzyme. The optimum pH was increased on immobilization but the addition calcium chloride caused a decrease. Compared to the soluble form the immobilized enzyme is less stable at 60 °C in calcium enriched buffers but more stable in calcium free buffers. The temperature-activity profile has a plateau between 40 °C and 60 °C attributable to a comformational change above 60 °C to a more active form. The action pattern in the hydrolysis of soluble starch was found to be unaffected by immobilization. Parameters affecting the amount of bound activity were studied. The magnetic recovery of the immobilized enzyme was complete.     

EFFECT OF SEVERAL EXPERIMENTAL PARAMETERS ON COMBINATION OF RED KIDNEY BEAN (PHASEOLUS VULGARIS) α-AMYLASE INHIBITOR WITH PORCINE PANCREATIC α-AMYLASE

Purified red kidney bean (Phaseolus vulgaris) amylase inhibitor forms a 1:1 stoichiometric complex with porcine pancreatic α-amylase leading to complete loss of enzyme activity on starch. Rate of complex formation is pH dependent and is maximal at pH 5. The rate constants for complex formation, as measured by loss of amylase activity, were 2.85 × 10⁴ M^-1 sec^-1 at pH 6.9 (ionic strength of 0.918) and 2.55 × 10⁵ M^-1 sec^-1 at pH 5 at 30°C. At pH 6.9, rate of complex formation was 4.8 times faster at 0.918 ionic strength as compared with the rate at 0.138 ionic strength. At 30°C, pH 6.9 and ionic strength of 0.168 the dissociation constant of the enzyme-inhibitor complex was determined to be 3.5 × 10^-11 M. The rate constant for dissociation of the complex was calculated to be 8.7 × 10^-8 sec^-1 under the same conditions. The rate constant for complex formation, at ionic strength of 0.168, was 1.1 × 10⁴ M^-1 sec^-1 at 37⁰ and 9.77 × 10² M^-1 sec^-1 at 25.7°C. The calculated activation energy for complex formation is 39.5 kcal/mole suggesting a rate-controlling conformational change. Oxidation of the carbohydrate moiety of the glycoprotein inhibitor caused complete loss of activity. Maltose, a competitive inhibitor of α-amylase, bound as readily to the enzyme-inhibitor complex as to free α-amylase. Trypsinized α-amylase, although still able to bind to Sephadex, did not bind inhibitor. The experiments with maltose and trypsinized amylase suggest the inhibitor may not bind at the active site of α-amylase.     

STRUCTURAL FEATURES OF RED KIDNEY BEAN á-AMYLASE INHIBITOR IMPORTANT IN BINDING WITH á-AMYLASE

The structural features of the glycoprotein α-amylase inhibitor from red kidney bean (Phaseolus vulgaris) important for binding to α-amylase were examined. The inhibitor contained 13.0% carbohydrate. The carbohydrate portion of the inhibitor is composed of 25 mannose, 2 xylose, 1 fucose and 17 N-cetylglucosamine residues per mol. Seventy (70) percent of the neutral carbohydrates were removed from the inhibitor by treatment with endo-β- N -acetylglucosaminidase H. The carbohydrate remaining attached to the protein consisted of 7 mannose, 2 xylose, and 1 fucose residues (N-acetylogucosamine was not determined). The intact glyco chains obtained from the pronase digest of the inhibitor failed to inhibit β-amylase (3.3 times 10⁵ fold molar excess of glyco chains to enzyme) when preincubated with the enzyme at 30°C for 30 min at pH 6.9 before adding starch as substrate.
Oxidation of one tryptophan residue of the α-amylase inhibitor with N-bromosuccinimide at pH 6.0 led to a 50% loss in inhibitory activity. Periodate oxidation of α-amylase inhibitor led to less of two tyrosine and one methionine residues per mole of inhibitor within 15 min. There was not a direct correlation between modification of these residues and loss of inhibitory activity. Modification of three of the five histidine residues with diethylpyrocarbonate resulted in about 50% loss in inhibitory activity.     

A Maltooligosaccharides Producing α-Amylase from Bacillus subtilis SDP1 Isolated from Rhizosphere of Acacia cyanophylla Lindley

Maltooligosaccharides producing amylases are required in the food industry, especially in breadmaking. The Bacillus subtilis strain SDP1 amylase hydrolyses starch to produce maltotriose and maltotetraose along with maltose after prolonged reactions of 5 h. Bacillus subtilis strain SDP1 was isolated from the rhizosphere of Acacia cyanophylla Lindley from the Çukurova region of Turkey. The highest enzyme production was achieved with soluble starch as the carbon and yeast extract as the nitrogen source and at pH 7.0 and 37°C. Under optimized culture conditions, 68.49 U/mL activity was obtained. SDP1 α-amylase had molecular weight of 61 kD. The optimum pH of the enzyme was 7.0 and was highly active at pH ranging from 5.0 to 9.0. The optimum temperature of the crude enzyme was 60°C, and it retained 83% and 74% of its initial activity after 1 h and 2 h incubation periods, respectively, at 50°C. While, Mn⁺² has a stimulatory effect on the activity, Ca⁺², Mg⁺², Na⁺ did not effect the enzyme activity. Fe⁺³, Ni⁺², Cu⁺² and Co⁺² had an inhibitory effect on SDP1 amylase activity.     

Characterization of honey amylase

ABSTRACT:  The major α-amylase in honey was characterized. The optimum pH range and temperature were determined for the enzyme as 4.6 to 5.3 and 55 °C, respectively. The enzyme was stable at pH values from 7 to 8. The half-lives of the purified enzyme at different temperatures were determined. The activation energy for heat inactivation of honey amylase was 114.6 kJ/mol. The enzyme exhibited Michaelis–Menten kinetics with soluble starch and gave K _M and V _max values of 0.72 mg/mL and 0.018 units/mL, respectively. The enzyme was inhibited by CuCl (34.3%), MgCl₂ (22.4%), and HgCl₂ (13.4%), while CaCl₂, MnCl₂, and ZnSO₄ did not have any effect. Starch had a protective effect on thermal stability of honey amylase. Therefore, it might be critical to process or control the amylase in honey before incorporation into starch-containing foods to aid in the preservation of starch functionality. One step could involve heat treating honey with other ingredients, especially those that dilute and acidify the honey environment.     

PASSION FRUIT STARCH AND EFFECT ON JUICE VISCOSITY

Starches in the juices of yellow passion fruit, Passiflora edulis f. flavicarpa , and purple passion fruit, P. edulis f. edulis , were isolated and characterized. Starch granule sizes for the yellow variety (7.8 μm) and purple variety (6.4 μm) were similar. Gelation temperature ranges for the yellow variety (58.5–67.0 ° c) and purple variety (58.5–66.5 ° C) were also similar. The amylose content was slightly higher in the yellow variety (8.7%) than in the purple variety (5.8%). Viscosity differences between juices of the two varieties after treatment with heat and α-amylase were attributed to differences in pH and starch content between the yellow variety (pH 2.8, 0.06% starch) and the purple variety (pH 4.2, 0.74% starch). α-amylase was effective in reducing the viscosity of passion fruit juice in which the starches are gelatinized.     

Sweetpotato α- and β-Amylases: Characterization and Kinetic Studies with Endogenous Inhibitors

Sweetpotato α- and β-amylases were characterized to assist optimization of direct hydrolysis of starch by endogenous amylases. In kinetic studies purified starch was substrate, and ascorbate, oxalate, phenolics, phytate and sweetpotato extracts were assayed for inhibitory activity. α-Amylase had optimum pH between 5.8 and 6.4 and was stable from pH 5.0 to 9.0. Optimum activity occurred at 71.5°, but it was inactivated by heat in the absence of Ca²⁺ at > 63°. The Km for soluble starch was 2.08 mg/mL. The molecular weight was 45000 daltons. α-Amylase activity was reduced up to 70% by 0.2 mM K-ascorbate and moderately by Na-oxalate and Na-phytate. β-Amylase had optimum pH between 5.3 and 5.8, and was stable from pH 4.0 to 8.0. Its maximum activity was at 53° and it was inactivated at 60°. Km for soluble starch was 3.71 mg/mL. At 0.08 mM, K-ascorbate strongly inhibited β-amylase activity.     

Activity of diastase α-amylase immobilized on polyanilines (PANIs)

Starch hydrolysing enzyme α-amylase (EC 3.2.1.1) was immobilized by physical adsorption and covalent binding onto chemically synthesised polymer, polyanilines (PANIs) in two different forms, emeraldine salt and emeraldine base powder. The immobilization efficiency was affected by the pH of the immobilization medium, contact time and amount of enzyme. The kinetic parameters, reusability and storage stability of the enzyme were studied under free and immobilized condition at optimum pH and temperature. The immobilized enzyme showed enhanced storage stability over a period of 6 months, while free enzyme in solution lost all of its activity within a period of 8 days. Reusability of the enzyme was improved by immobilization. The K_m values for starch hydrolysis were found to be high for the immobilized enzymes.     

Characteristics and Novel Features of Thermostable α-Amylase Produced by Bacillus licheniformis M27 under Solid State Fermentation

The purified α-amylase from Bacillus licheniformis M27, produced under solid state fermentation technique, showed novel characteristics as compared to those reported by other workers for the purified α-amylases from B. licheniformis obtained by submerged fermentation process. Some of the novel features of the characteristics of the enzyme from B. licheniformis M27 include two peaks for pH optima at 6.5–7.0 and 8.5–9.0, gradual loss of activity to about 86% between pH 7.0–7.5 followed by rise to full activity between 7.5–8.5, temperature optimum at 85–90°C at pH 7.0 and 9.0, sharp fall in stability at acidic pH values and the thermostability response which is more similar to the enzyme from other species of Bacillus. The moleculuar weight of the enzyme was found to be 19,500 ± 500 and 56,000 ± 2,000 when determined by gel filtration and SDS PAGE, respectively. The activation energy is 20.4 times lower than that reported for the enzyme from another strain of B. licheniformis. It also showed differences in the contents of amino acids such as serine, proline and methionine.     

α-Amylases in raw and fermented African oil bean seeds (Pentaclethra macrophylla benth)

The !-amylases of raw and fermented seeds of African oil bean (Pentaclethra macrophylla Benth) were isolated, partially purified (tenfold) and subjected to different thermal and pH conditions. The specific activities of the purified enzyme from raw and fermented seeds were 0.037 ml^-1 min^-1 and 0.88 ml^-1 min^-1 respectively. The !-amylase from fermented seeds was more thermostable with optimum activity at 70 °C, compared to the optimum temperature of 60 °C obtained for the raw seed enzyme. The assayed !-amylases were stable over a wide range of pH (3.0-7.0), with optimum activity found at pH 6.0 and pH 5.0 for raw and fermented seeds respectively. The results show that the !-amylase of Pentaclethra macrophylla complements the microbial amylases in the mainly bacterial fermentation of African oil bean seeds to 'ugba', a highly nutritious food condiment. While the !-amylase in the raw seeds was basically the plant enzyme, that isolated from the fermented seeds was a combination of plant and microbial !-amylases.     

MOLECULAR PROPERTIES OF POST-MORTEM MUSCLE. 9. Effect of Temperature and pH on Tropomyosin-Troponin and Purified α-Actinin from Rabbit Muscle

SUMMARY– A study was done on the effects of in vitro storage of purified α-actinin, troponin, tropomyosin, and the tropomyosin-troponin complex on the activity of these protein fractions in the ATPase and superprecipitation assays. Storage was done at various combinations of temperatures between 0 and 40°C and pH values between 5.7 and 7.0. Even after 40 hr of storage, activities of purified tropomyosin and the tropomyosin-troponin complex were not affected by any combination of temperature and pH included in this study, but activities of purified α-actinin and troponin were almost completely lost after 16 hr at 40°C and pH 5.7. Storage for 40 hr at low pH (5.7) and low temperatures (0°C) did not affect the activity of either α-actinin or troponin, but 40 hr of storage at high temperatures (40°C) and neutral pH caused some loss in activity for both these proteins. This loss of activity caused by 40°C, pH 7.0 storage was much more noticeable in the case of troponin than in the case of α-actinin. Storage periods of 40 hr or longer were required before any loss of α-actinin activity could be detected at pH 7.0 and 40°C. Since most meat animal carcasses are chilled soon after exsanguination and attain muscle temperatures of 25°C or lower before the pH falls below 6.2, it is probable that α-actinin and tropomyosin-troponin activity remain almost unchanged in meat handled through normal market channels. However, myofibrillar tissue in those porcine animals whose musculature undergoes a very rapid post-mortem decline in pH so that values of 5.7 or less are reached while muscle temperatures are still 37°C or higher may lose much of its α-actinin and tropomyosin-troponin activity during the first 24 hr post-mortem.     

Purification and Characterization of the Commercialized,Cloned Bacillus megaterium α-Amylase. Part I: Purification and Hydrolytic Properties

An amylolytic enzyme, originally isolated from Bacillus megaterium. was shown to increase the maximum amount of dextrose produced during saccharification by decreasing the amount of residual oligosaccharides. The enzyme, now commercially produced in a genetically engineered strain of Bacillus subtilis, was purified to homogeneity from the commercial product. A combination of gel permeation chromatography in the presence of 1.0 M NaCl and chromatofocusing between pH 9.0 and 7.0 were used to obtain the pure enzyme. The molecular weight of the Bacillus megaterium α-amylase was 59,000 by SDS gel electrophoresis, and the isoelectric point was 8.9 to 9.0. The enzyme was shown to possess both hydrolytic and transferase activity. The enzyme hydrolyzed a wide variety of soluble substrates. The rate of hydrolysis was greatest on soluble starch; α(1,6)-branched substrates and cyclodextrins were hydrolyzed more slowly.     

磁性聚乙烯醇微球固定化β-淀粉酶的研究

磁性聚乙烯醇微球为载体,采用戊二醛交联法固定化β-淀粉酶,并对固定化酶的理化性质等进行了研究。结果表明,磁性固定化β-淀粉酶的总活力、蛋白载量、比活、活性回收率分别为7207.62 U/g,157.21 mg/g,45.85 U/mg和52.38%;固定化β-淀粉酶的反应最适温度和最适pH分别为70℃和5.O;Fe~(2+)和Cu~(2+)对β-淀粉酶有较强的抑制作用,而Zn~(2+)对其有很强的激活作用,Mg~(2+)则不影响β-淀粉酶的活性;β-淀粉酶被固定化后其热稳定性(在水介质中)、操作稳定性、pH稳定性均比自由酶的明显提高。固定化β-淀粉酶在4℃,pH 4.5的缓冲液中保存31 d,其活力仍保持最初活力的98.3%,这比其自由酶的提高26%。     

PURIFICATION AND PHYSICOCHEMICAL PROPERTIES OF AN EXTRA CELLULAR AMYLASE FROM A STRAIN OF BACILLUS AMYLOLIQUEFACIENS ISOLATED FROM DRY ONION POWDER

An extracellular α-amylase from Bacillus amyloliquefaciens, isolated from dry onion powder, has been purified to homogeneity by ammonium sulfate fractionation, adsorption on starch, column chromatography on DEAE-cellulose, and gel filtration on Sephadex G-100 column. The enzyme consisted of one polypeptide chain with a molecular weight of 60,000. The isoelectric point was pH 5.2, the pH optimum 5.5 and the temperature optimum ranging from 50°-70°C. Prolonged digestion by trypsin did not affect the catalytic properties of the enzyme. The K_m for starch was 6.9 mg/ml. The enzyme was quite stable at 50°C, but lost about 85% of its activity at 60° after 30 min (pH 6.0).     

Sulfolobus tokodaii strain 7高温酸性α-淀粉酶基因在大肠杆菌中克隆表达及其酶学性质

以超嗜热古菌Sulfolobus tokodaii strain 7基因组DNA为模板,通过PCR扩增高温酸性α-淀粉酶基因ST0817,将此基因克隆至表达载体pET15b,并转化大肠杆菌Escherichia coli BL21-CodenPlus(DE3)-RIL,获得重组大肠杆菌工程菌。通过热处理、镍柱亲和层析和分子筛层析,得到纯化重组酶,SDS-PAGE分析表明,该酶分子量为53.0 kDa。酶学性质研究表明,该酶最适温度和pH分别为75℃和5.5;具有较强的热稳定性和pH稳定性,在85℃处理8 h保持50%左右活力,在pH 5.2处理120 min仍保持50%活力。此酶对不同底物水解活性不同,直连淀粉>可溶性淀粉>支链淀粉>β-极限糊精>糖原>环糊精>普鲁兰糖;该酶对有机溶剂、变性剂和金属离子具有一定抗性。     

Glucoamylase Covalently Bound to Acrylic Carriers

Glucoamylase from Aspergillus niger was covalantly bound to three acrylic carriers differing in the content of amino groups, particle size, porosity, etc. Yield of immobilization ranged from 58.7% to 87.0%. Enzyme immobilized on Vinylaff 818 was the most stable. That carrier was a copolymer of butyl acrylate and ethylene dimethacrylate, containing 0.44 mmol/g of amino groups. The immobilized catalyst used for hydrolysis of 40% maltodextrin solution (DE 18.3) retained its initial activity at 50°C for about 33 d. The pretreatment of soluble glucoamylase with low concentrated glutaraldehyde solution (0.13%, 1.4 mg/100 mg of protein) increased the operational stability of immobilized enzyme to about 50 d and its half-life to 60 d. The immobilization of enzyme on Vinylaff 818 resulted in the slight shift of pH optimum to acid side, though it did not influence the temperature optimum. Thermostability of immobilized glucoamylase in the range of temperature between 50 and 75°C was higher than that of soluble enzyme. Maximum concentrations of glucose in hydrolyzates were obtained in relatively short time. The prolonged hydrolysis of concentrated starch substrate by enzyme immobilized on the porous carrier caused, however, the accumulation of disaccharides with simultaneous reduction of glucose content.     

USE OF IMMOBILIZED LACTASE IN PROCESSING CHEESE WHEY ULTRAFILTRATE

Enzymatic hydrolysis of lactose in cottage cheese whey ultrafiltrate was investigated. Lactase of A. niger was immobilized on an alumina-silica catalyst support by the linking agent tolylene-2, 4-diisocyanate. The resulting immobilized enzyme preparation had an activity of 3 standard international units of lactase per gram at pH 4 and 37 °C. The optimum pH and temperature for hydrolysis of lactose by immobilized lactase were 3.5 and 50°C, respectively. Immobilization of the enzyme resulted in reductions of 1.1 pH units and 15°C in optimum pH and temperature, respectively. The two constants of the simple Michaelis-Menten rate expression were obtained from Lineweaver-Burk plots of the initial reaction rate data obtained at 37°C. Estimated values for V_max and the apparent K_m were 7.8 (μmoles/min-g) and 0.26 (M), respectively. Inhibition by the product galactose was measured by studying the hydrolysis reaction in a batch reactor. The inhibition constant K_i was estimated from batch reactor data to be 0.005 and 0.053 (M) at 35 and 50°C, respectively. Activation energies of 8.1 and 6.4 (kcal/gmole) were obtained for the immobilized and soluble enzyme reactions, respectively. The behavior of the batch reactor as measured in terms of a plot of conversion versus time was essentially the same for both conventional and deionized whey ultrafiltrate.     

Purification and Characterization of β-amylase from Bacillus polymyxa No. 26-1

An extracellular β-amylase, which was easily adsorbable onto raw corn starch, was purified 22.5-fold from a new isolate of Bacillus polymyxa No 26–1 with a M_r of 53 kDa and pI of 9.1. The optimum temperature was 45°C and pH 5.5 for raw corn starch. Thermal stability at 40°C and pH stability at 5.0–8.5 were shown. The degradation ofraw starch by β-amylase was greatly stimulated by pullulanase addition. Scanning electron micrographs revealed that starch granule degradation by the enzyme alone occured at the equatorial grooves of lecticular granules. Corn starch granules hydrolyzed by β-amylase had large holes on granule surfaces.     

ASSESSMENT OF BACILLUS LICHENIFORMIS α-AMYLASE AS A CANDIDATE ENZYME FOR GENETIC ENGINEERING OF MALTING BARLEY1

Bacillus licheniformis α-amylase, a thermostable starch-degrading enzyme, has been assessed as a candidate enzyme for the genetic transformation of malting barley. The temperature optimum, pH optimum and thermostability of B. licheniformis α-amylase were compared with those of barley α-amylase. The bacterial enzyme has a higher pH optimum (?9), a higher temperature optimum (?90°C) and much higher thermostability at elevated temperatures than the barley enzyme. The specific activity of the bacterial enzyme under conditions of pH and temperature relevant to the brewing process (pH 5.5, 65°C) is ?1.5-fold higher than that of the barley enzyme. Measurements of α-amylase activity during a micro-mash showed that the bacterial enzyme is at least as stable as the barley enzyme under these conditions, and that a level of expression for the bacterial enzyme corresponding to ?0.5% of total malt protein would approximately double the α-amylase activity in the mash. B. licheniformis α-amylase activity was rapidly eliminated by boiling following mashing as would occur during brewing. The combined results suggest that barley expressing the bacterial enzyme may be useful in the brewing process.     

Preparation and characterization of immobilized beta-lactamase for destruction of penicillin in milk

beta-Lactamase I (Bacillus cereus) was covalently bound to cyanogen bromide-activated, crosslinked agarose. An initial 5.00 mg of soluble beta-lactamase were used in the immobilization reaction for each preparation, and average coupling yield was 80.5%. Of the enzyme immobilized on the matrix, an average 53.4% remained active. To minimize diffusional effects on immobilized enzyme activity, reaction mixtures were rotated at 250 rpm throughout the study. The shape of the pH activity curve of the immobilized enzyme was identical to that of the soluble enzyme; both exhibited optimum pH around 7.0. In general, only 2-fold differences in Michaelis constant and maximum volume were observed between native and immobilized enzyme when penicillin G was used as the substrate. However, the Michaelis constant of the immobilized enzyme increased up to 22-fold that of the native enzyme when cephaloridine was used as the substrate. The immobilized enzyme exhibited enhanced stability in the acidic pH region in contrast to the native enzyme, which had superior stability in the alkaline pH region. The heat stability of the immobilized enzyme was about twice that of native enzyme after heat treatment at 60 degrees C for 30 min. Approximately a 10% increase of storage stability on immobilization of beta-lactamase was observed when stored at room temperature (23 +/- 1 degree C) for up to 6 d in the absence of antimicrobial agents. Little loss of activity (less than 2%) was noted after repeated use of the immobilized enzyme up to seven times each in 10.0 ml of skim milk containing .5 U/ml penicillin G.(ABSTRACT TRUNCATED AT 250 WORDS)