Investigation of α-amylase and proteinase of culture filtrate from bacillus licheniformis MB 80 strain

At the investigation of some properties of the α-amylase and proteinase in the culture filtrat from Bacillus licheniformis MB 80 strain it has been established that the α-amylase activity is the highest at pH 6.0 to 6.5 and at 90°C, that the proteolytic activity is the highest at pH 9.5 to 10.0 and at 70°C and that the proteinase is inactivated at temperatures over 70°C.     

Fermentation production of keratinase from Bacillus licheniformisPWD-1 and a recombinant B. subtilis FDB-29

Bacillus licheniformis PWD-1, the parent strain, and B. subtilis FDB-29, a recombinant strain. In both strains, keratinase was induced by proteinaceous media, and repressed by carbohydrates. A seed culture of B. licheniformis PWD-1 at early age, 6–10 h, is crucial to keratinase production during fermentation, but B. subtilis FDB-29 is insensitive to the seed culture age. During the batch fermentation by both strains, the pH changed from 7.0 to 8.5 while the keratinase activity and productivity stayed at high levels. Control of pH, therefore, is not necessary. The temperature for maximum keratinase production is 37°C for both strains, though B. licheniformis is thermophilic and grows best at 50°C. Optimal levels of dissolved oxygen are 10% and 20% for B. licheniformis and B. subtilis respectively. A scale-up procedure using constant temperature at 37°C was adopted for B. subtilis. On the other hand, a temperature-shift procedure by which an 8-h fermentation at 50°C for growth followed by a shift to 37°C for enzyme production was used for B. licheniformis to shorten the fermentation time and increase enzyme productivity. Production of keratinase by B. licheniformis increased by ten-fold following this new procedure. After respective optimization of fermentation conditions, keratinase production by B. licheniformis PWD-1 is approximately 40% higher than that by B. subtilis FDB-29. Received 16 July 1998/ Accepted in revised form 07 March 1999     

Potato peel as a solid state substrate for thermostable α-amylase production by thermophilic Bacillus isolates

Summary Potato peel was found to be a superior substrate for solid state fermentation, compared to wheat bran, for the production of α-amylase by two thermophilic isolates of Bacillus licheniformis and Bacillus subtilis. Under optimal conditions, B. licheniformis produced 270 units/ml and 175 units/ml of α-amylase on potato peel and wheat bran, respectively, while the corresponding values for B. subtilis were 600 units/ml and 265 units/ml. The enzyme from B.␣licheniformis was optimally active at 90 °C and pH 9.0, while that from B. subtilis at 60 °C and pH 7.0. The nature of the experimental data permitted excellent polynomial fits, on the basis of which, two master equations, corresponding to the isolated strains, were derived for estimation of enzyme activity for any set of values of temperature, particle size, moisture, and incubation time within the indicated ranges.     

Applications of a high maltose forming,thermo-stable α-amylase from an extremely alkalophilic Bacillus licheniformis strain AS08E in food and laundry detergent industries

An alkalophilic bacterial strain was isolated from the soil sample of Assam, North-East India. This strain was found capable of growing and producing α-amylase at extremely alkaline pH (12.5). By molecular characterization, this bacterium was identified as Bacillus licheniformis strain AS08E. Statistical optimization of media components resulted in 3-fold increase in the production of α-amylase from this bacterium. From this strain, a major extracellular α-amylase of ∼55 kDa was purified to homogeneity with a 14.5-fold increase in its specific activity. The N-terminal sequence of this enzyme showed extensive identity with α-amylases purified from thermostable bacteria. The purified enzyme showed optimum activity at pH 10.0 and 80 °C, and demonstrated stability toward various surfactants, organic solvents, and commercial laundry detergents. The spectroflurometric analysis suggests that the enzyme has a strong binding affinity toward soluble starch. TLC analysis of starch degradation product displays this α-amylase as a high maltose-forming enzyme. The future application of this enzyme in food and detergent industries is highly promising.     

Culture conditions for the production of amylolytic enzymes by a thermophilic Clostridium sp.

The growth of a thermophilic Clostridium sp. and the production of α-glucosidase, α-amylase and pullulanase were studied under anaerobic conditions using different carbon and nitrogen sources and varying pH values and temperatures. Growth and enzyme activities were highest with soybean meal as the nitrogen source. The optimum concentration was 2.5% [w/v] for the production of α-amylase as well as pullulanase and 2% [w/v] for α-glucosidase. The best carbon source proved to be soluble starch for α-amylase, and pullulanase and maltose for α-glucosidase. Growth and enzyme production reached their optimum at pH 6.5 to 7.0 and 70°C. Under these conditions, the enzyme activities followed exponential growth with maximum yields of α-glucosidase, α-amylase and pullulanase at 28, 36, and 44 h.     

Chicken feathers: a complex substrate for the co-production of α-amylase and proteases by <Emphasis Type="Italic">B. licheniformis</Emphasis> NH1

This study is concerned with the co-production of alkaline proteases and thermostable α-amylase by some feather-degrading Bacillus strains: B. mojavensis A21, B. licheniformis NH1, B. subtilis A26, B. amyloliquefaciens An6 and B. pumilus A1. All strains produced both enzymes, except B. pumilus A1, which did not exhibit amylolytic activity. The best enzyme co-production was obtained by the NH1 strain when chicken feathers were used as nitrogen and carbon sources in the fermentation medium. The higher co-production of both enzymes by B. licheniformis NH1 strain was achieved in the presence of 7.5 g/l chicken feathers and 1 g/l yeast extract. Strong catabolic repression on protease and α-amylase production was observed with glucose. Addition of 0.5% glucose to the feather medium suppressed enzyme production by B. licheniformis NH1. The growth of B. licheniformis NH1 using chicken feathers as nitrogen and carbon sources resulted in its complete degradation after 24 h of incubation at 37°C. However, maximum protease and amylase activities were attained after 30 h and 48 h, respectively. Proteolytic activity profiles of NH1 enzymatic preparation grown on chicken feather or casein-based medium are different. As far as we know, this is the first contribution towards the co-production of α-amylase and proteases using keratinous waste. Strain NH1 shows potential use for biotechnological processes involving keratin hydrolysis and industrial α-amylase and proteases co-production. Thus, the utilization of chicken feathers may result in a cost-effective process suitable for large-scale production.     

Bioemulsifier production by a halothermophilic Bacillus strain with potential applications in microbially enhanced oil recovery

A halothermotolerant Gram-positive spore-forming bacterium was isolated from petroleum reservoirs in Iran and identified as Bacillus licheniformis sp. strain ACO1 by phenotypic characterization and 16S rRNA analysis. It showed a high capacity for bioemulsifier production and grew up to 60°C with NaCl at 180 g l⁻¹. The optimum NaCl concentration, pH and temperature for bioemulsifier production were 4% (w/v), 8.0, and 45°C, respectively. Although ACO1 did not utilize hydrocarbons, it had a high emulsifying activity (E ₂₄ = 65 ± 5%) on different hydrophobic substrates. Emulsification was optimal while growing on yeast extract as the sole carbon source and NaNO₃ as the nitrogen source. The efficiency of the residual oil recovery increased by 22% after in situ growth of B. licheniformis ACO1 in a sand-pack model saturated with liquid paraffin.     

Purification and Characterization of a Novel Fungal α-Glucosidase from Mortierella alliacea with High Starch-hydrolytic Activity

The fungal strain Mortierella alliacea YN-15 is an arachidonic acid producer that assimilates soluble starch despite having undetectable α-amylase activity. Here, a α-glucosidase responsible for the starch hydrolysis was purified from the culture broth through four-step column chromatography. Maltose and other oligosaccharides were less preferentially hydrolyzed and were used as a glucosyl donor for transglucosylation by the enzyme, demonstrating distinct substrate specificity as a fungal α-glucosidase. The purified enzyme consisted of two heterosubunits of 61 and 31 kDa that were not linked by a covalent bond but stably aggregated to each other even at a high salt concentration (0.5 M), and behaved like a single 92-kDa component in gel-filtration chromatography. The hydrolytic activity on maltose reached a maximum at 55°C and in a pH range of 5.0-6.0, and in the presence of ethanol, the transglucosylation reaction to form ethyl-α-D-glucoside was optimal at pH 5.0 and a temperature range of 45-50°C.     

Production of α-amylase in a low cost medium by Bacillus licheniformis TCRDC-B13

A low cost synthetic medium producing large quantities of α-amylase has been developed. Bacillus licheniformis TCRDC-B13 isolated from soil was used for α-amylase production. The α-amylase enzyme of this strain showed excellent stability at high temperatures and over a wide pH range. The low cost medium produced 5 times more enzyme than the high cost synthetic medium (using yeast extract and peptone) in shake flasks. In a 2.6-l fermentor, the enzyme production further doubled.     

An organic solvent-, detergent-, and thermostable alkaline protease from the mesophilic, organic solvent-tolerant Bacillus licheniformis 3C5

Bacillus licheniformis 3C5, isolated as mesophilic bacterium, exhibited tolerance towards a wide range of non-polar and polar organic solvents at 45°C. It produced an extracellular organic solvent-stable protease with an apparent molecular mass of approximately 32 kDa. The inhibitory effect of PMSF and EDTA suggested it is likely to be an alkaline serine protease. The protease was active over a broad range of temperatures (45–70°C) and pH (8–10) range with an optimum activity at pH 10 and 65°C. It was comparatively stable in the presence of a relatively high concentration (35% (v/v)) of organic solvents and various types of detergents even at a relatively high temperature (45°C). The protease production by B. licheniformis 3C5 was growth-dependent. The optimization of carbon and nitrogen sources for cell growth and protease production revealed that yeast extract was an important medium component to support both cell growth and the protease production. The overall properties of the protease produced by B. licheniformis 3C5 suggested that this thermo-stable, solvent-stable, detergent-stable alkaline protease is a promising potential biocatalyst for industrial and environmental applications.     

Silica carriers for immobilization of thermostable α-amylase

The possibilities for immobilization of thermostable α-amylase from Bacillus licheniformis 44MB82 on silica carriers activated by different methods have been studied. Immobilization on Ti(IV)-activated CPG, Chromosorb P, quartz powder and pumice stone was sufficiently effective. The preparation immobilized on CPG showed a shift in pH and temperature-profiles of enzyme action. They were found to be changed from pH 6,0–6,5 to pH 8,5 and from 90°C to 80°C, respectively, when compared to these parameters of the soluble enzyme. Immobilization leads to enhancement of thermostability. Possibilities for batchwise use of the immobilized preparation were established.     

A thermophilic extracellular -amylase from Bacillus licheniformis

A strain of Bacillus licheniformis isolated from soil produced an extracellular α-amylase(s) with unusual characteristics. The enzyme was purified 126-fold by starch adsorption, DEAE-cellulose treatment, and CM-cellulose column chromatography. Four active protein bands were detected by disc electrophoresis in poly-acrylamide gel although the enzyme behaved as a single peak during both ultracen-trifugation and chromatography using CM-cellulose and Sephadex G-100. The enzyme showed a very broad pH-activity curve and had substantial activity in the alkaline range. The optimal temperature was 76 °C at pH 9.O. The enzyme was stable between pH 6 and 11 at 25 °C, and below 60 °C at pH 8.0. Using Sephadex G-100 gel filtration, a molecular weight of 22,500 was estimated for the enzyme. The action pattern on amylose and amylopectin is unique in that the predominant product during all stages of hydrolysis is maltopentaose.     

Charakterisierung der Stärkehydrolysate nach Einwirkung einer thermostabilen α-Amylase

The action of thermostable α-amylase produced by Bacillus licheniformis 44MB82 strain on soluble and insoluble starch, amylose and amylopectin at temperatures 30°C and 90°C was studied. The hydrolysis of soluble starch proceeded rapidly for 10 to 15 minutes after which the maltodextrins thus formed were further dissociated. In the course of 60-minutes enzyme treatment mainly glucose, maltose and maltosugars (from G₃ to G₆) as low molecular weight products were found and the formation of maltcse and maltotriose was increased by the longer treatment. The hydrolysis of insoluble starch and amylopectin proceeded in the same way while the amylose was hydrolysed slowly.     

Truncated α-amylase: an improved candidate for textile processing

Abstract

Enzymes are indispensable biocatalysts required in various steps of textile processing to minimize various chemical-induced hazards. The present work focuses on the applications of the truncated α-amylase in textile industry for desizing of fabrics by starch hydrolysis. The multiple sequence alignment was performed to find homology and the possible truncation region in Bacillus subtilis MTCC 121 α-amylase with same bacilli family α-amylase. Two constructs were generated for α-amylase gene of Bacillus subtilis MTCC 121 (Amy_F, full-length and Amy_T, C-terminal truncated) were cloned, overexpressed, purified, and characterized. Results revealed that activity of Amy_T was found to be 2.87-fold better than Amy_F. Further, the optimum temperature of Amy_F and Amy_T was obtained at 45?°C and 55?°C, respectively, whereas optimum pH was recorded at pH 7 and pH 8, respectively. Improved thermostability of Amy_T was further confirmed through thermal shift assay. Subsequently, starch-coated fabrics were tested for starch removal using the α-amylases. Comparative analysis revealed that Amy_T performed better in starch removal from polystyrene (85%), silk (75%), and cotton (70%) fabrics. The removal of starch from the fabrics was further confirmed by FESEM. Conclusively, this work presents one truncated α-amylase as an improved candidate over its full-length counterpart for textile desizing.     

Purification and Some Properties of Acid-stable α-Amylases from Shochu koji (Aspergillus kawachii)

Aspergillus kawachii α-amylase [EC 3.2.1.1] I and II were purified from shochu koji extract by DEAE Bio-Gel A ion exchange chromatography, Sephacryl S-300 gel chromatography (pH 3.6), coamino dodecyl agarose column chromatography and Sephacryl S-200 gel chromatography. By gel chromatography on a Sephacryl S-300 column, the molecular weights of the purified α-amylase I and II were estimated to be 104,000 and 66,000, respectively. The isoelectric points of α-amylase I and II were 4.25 and 4.20, respectively. The optimal pH range of α-amylase I was 4.0 to 5.0, and the optimum pH of α-amylase II was 5.0. The optimum temperatures of both α-amylases were around 70°C at pH 5.0. Both α-amylases were stable from pH 2.5 to 6.0 and up to 55°C, retaining more than 90% of the original activities. Heavy metal ions such as Hg^{2 +} and Pb^{2 +} were potent inhibitors for both α-amylases.     

Thermostable mutant variants of Bacillus sp. 406 α-amylase generated by site-directed mutagenesis

Several mutations are known to increase the thermostability of α-amylase of B. licheniformis and other α-amylases. Site-directed mutagenesis was used to introduce similar mutations into the sequence of the α-amylase gene from mesophilic Bacillus sp. 406. The influence of the mutations on thermostability of the enzyme was studied. It was shown that the Gly211Val and Asn192Phe substitutions increased the half-inactivation temperature (T_m) of the enzyme from 51.94±0.45 to 55.51±0.59 and 58.84±0.68°C respectively, in comparison to the wild-type enzyme. The deletion of Arg178-Gly179 (dRG) resulted in an increase of T_m of the α-amylase to 71.7±1.73°C. The stabilising effect of mutations was additive. When combined they increase the T_m of the wild-type amylase by more than 26°C. Thermostability rates of the triple mutant are close to the values which are typical for industrial heat-stable α-amylases, and its ability to degrade starch at 75°C was considerably increased. The present research confirmed that the Gly211Val, Asn192Phe and dRG mutations could play a significant role in thermostabilization of both mesophilic and thermophilic α-amylases.     

Cellulase from Bacillus licheniformis and Brucella sp. isolated from mangrove soils of Mahanadi river delta,Odisha, India

In the present study, two cellulose-degrading bacteria (CDB-5 and CDB-12) were isolated from mangrove soils of Mahanadi river delta, based on halo zone formation in Congo red agar medium and evaluation for cellulase production in CMC broth medium. Based on morphological, biochemical and 16S rRNA gene sequencing, the two strains, CDB-5 and CDB-12, were identified as Brucella sp. and Bacillus licheniformis, respectively. The gene bank accession number of the strains CDB-5 and CDB-12 are KR632646 and KR632645, respectively. The strain Brucella sp. and B. licheniformis showed an enzyme activity of 96.37?U/ml and 98.25?U/ml, respectively, after 72?h of incubation period. Enzyme production was optimized under different growth conditions such as pH, temperature, agitation rate, carbon source, sodium chloride (NaCl), and nitrogen sources. Maximum cellulase production by both the strains was obtained in the same parameter condition such as pH (7.0), rpm (150), and NaCl (2%, w/v) which varies for other parameters. The strain, CDB-5, produced maximum cellulase at 35?°C temperature, maltose as a carbon source, and yeast extract as a nitrogen source where as the strain CDB-12 produces maximum cellulase at 45?°C temperature, carboxyl methyl cellulose (CMC) as carbon source and trypton as a nitrogen source. The bacterial crude enzyme was purified by ammonium sulfate precipitation followed by overnight dialysis. SDS-PAGE analysis of the partially purified cellulase enzyme exhibited band sizes of approximately 55 and 72?kDa.     

Chitinase production by <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> and <Emphasis Type="Italic">Bacillus licheniformis</Emphasis>: Their potential in antifungal biocontrol

Thirty bacterial strains were isolated from the rhizosphere of plants collected from Egypt and screened for production of chitinase enzymes. Bacillus thuringiensis NM101-19 and Bacillus licheniformis NM120-17 had the highest chitinolytic activities amongst those investigated. The production of chitinase by B. thuringiensis and B. licheniformis was optimized using colloidal chitin medium amended with 1.5% colloidal chitin, with casein as a nitrogen source, at 30°C after five days of incubation. An enhancement of chitinase production by the two species was observed by addition of sugar substances and dried fungal mats to the colloidal chitin media. The optimal conditions for chitinase activity by B. thuringiensis and B. licheniformis were at 40°C, pH 7.0 and pH 8.0, respectively. Na⁺, Mg²⁺, Cu²⁺, and Ca²⁺ caused enhancement of enzyme activities whereas they were markedly inhibited by Zn²⁺, Hg²⁺, and Ag⁺. In vitro, B. thuringiensis and B. licheniformis chitinases had potential for cell wall lysis of many phytopathogenic fungi tested. The addition of B. thuringiensis chitinase was more effective than that of B. licheniformis in increasing the germination of soybean seeds infected with various phytopathogenic fungi.     

Stepwise Introduction of Regulatory Genes Stimulating Production of α-Amylase into Bacillus subtilis : Construction of an α-Amylase Extrahyper Producing Strain

The production of extracellular α-amylase in Bacillus subtilis is probably regulated by many genetic elements, such as amyR, tmrA7, pap, amyB and sacU. Additional genetic elements, C-108 and A-2 for production of the α-amylase were found in D-cycloserine and ampicillin resistant mutants (C108 and A2) of B. subtilis 6160, respectively. Strain C108 increased the production of α-amylase about 5 times and protease about 80 times compared to parental 6160 strain. Strain A2 showed a nearly 6-fold increased α-amylase production.

These genetic elements displayed a synergistic effect with other genetic factors in production of extracellular α-amylase when these elements were transferred by DNA mediated transformation. By stepwise introduction of these and other genetic elements into B. subtilis 6160 by transformation and mutation, strains with higher α-amylase producing activity were obtained. The finally obtained strain, T2N26, produced about 1,500-2,000 times more α-amylase than parental 6160 strain.     

Immunological comparison of bacterial α-amylases and multiple forms of Baci1lus licheniformis enzyme

A purified preparation of Bacillus licheniformis α-amylase was immunologeeally and electrophoretically compared with commercial crystalline α-amylase of Bacillus subtilis. The former enzyme reacted completely with rabbit antiserum to the same enzyme showing a single precipitin band, and moved toward the cathode in immuno-electrophoresis on agarose at pH 9.6. On the contrary, crystalline α-amylase of Bacillus subtilis migrated to the anode in immunoelectrophoresis at pH 8.6, though it weakly cross-reacted with the antiserum, suggesting that amylases of Bacillus licheniformis and Bacillus subtilis are not identical. In addition, the neutralization test of amylase activity showed that α-amylase of Bacillus licheniformis was much more susceptible to inhibition by the serum than was Bacillus subtilis α-amylase. Each of four species of Bacillus licheniformis α-amylase extracted from the sliced discs after disc electrophoresis on polyacrylamide gel was distinct from the others by showing individual migratory rate, but they were antigenically similar to each other and to the parent enzyme.