Structure-based engineering of alkaline α-amylase from alkaliphilic Alkalimonas amylolytica for improved thermostability

This study aimed to improve the thermostability of alkaline α-amylase from Alkalimonas amylolytica through structure-based rational design and systems engineering of its catalytic domain. Separate engineering strategies were used to increase alkaline α-amylase thermostability: (1) replace histidine residues with leucine to stabilize the least similar region in domain B, (2) change residues (glycine, proline, and glutamine) to stabilize the highly conserved α-helices in domain A, and (3) decrease the free energy of folding predicted by the PoPMuSiC program to stabilize the overall protein structure. A total of 15 single-site mutants were obtained, and four mutants — H209L, Q226V, N302W, and P477V — showed enhanced thermostability. Combinational mutations were subsequently introduced, and the best mutant was triple mutant H209L/Q226V/P477V. Its half-life at 60 °C was 3.8-fold of that of the wild type and displayed a 3.2 °C increase in melting temperature compared with that of the wild type. Interestingly, other biochemical properties of this mutant also improved: the optimum temperature increased from 50 °C to 55 °C, the optimum pH shifted from 9.5 to 10.0, the stable pH range expanded from 7.0–11.0 to 6.0–12.0, the specific activity increased by 24 %, and the catalytic efficiency (k _cat/K _m) increased from 1.8×10⁴ to 3.5?×?10⁴ l/(g min). Finally, the mechanisms responsible for the increased thermostability were analyzed through comparative analysis of structure models. The structure-based rational design and systems engineering strategies in this study may also improve the thermostability of other industrial enzymes.     

Studies on the thermostability of the α-amylase of Bacillus caldovelox

Summary Molecular mechanisms of thermoinactivation of the thermostable -amylase of Bacillus caldovelox were examined. Monomolecular conformational processes were found to be the major causes of thermoinactivation at both pH 4.5 and 8.0. The enzyme possessed considerable additional thermostability at pH 8.0, with half-lives of 0.75 and 7.0 min at 90° C and pH 4.5 and 8.0, respectively. The amino acid composition was examined with respect to the underlying thermostability exhibited by this enzyme. The inherent thermostability exhibited may be due to the high proline content (4.47 mol%), but more likely due to the high content of residues forming hydrophobic bonds (60.89 mol%) allied to a low content of residues responsible for ionic interactions (28.34 mol%). Offprint requests to: C. T. Kelly     

Effect of additives on the thermostability ofBacillus stearothermophilus α-amylase

The effect of additives on the thermostability ofBacillus stearothermophilus -amylase was determined. Polyols, dimethyl formamide, and dimethyl sulfoxide all increased the half life of the enzyme approximately 2-fold when tested at a 10% (w/v) addition. These results suggest that the enzyme's structure is stabilized against thermal denaturation through ionic interactions. Addition of dextran or polyvinyl alcohol (hydrophilic polymers which increase the viscosity of the solution) had a slight positive effect on enzyme stability while addition of polyethylene glycol or polyvinylpyrrolidone (hydrophobic polymers which increase the viscosity of the solution) resulted in a 2-fold decrease in enzyme half life.     

In Silico Rational Design and Systems Engineering of Disulfide Bridges in the Catalytic Domain of an Alkaline α-Amylase from Alkalimonas amylolytica To Improve Thermostability

High thermostability is required for alkaline α-amylases to maintain high catalytic activity under the harsh conditions used in textile production. In this study, we attempted to improve the thermostability of an alkaline α-amylase from Alkalimonas amylolytica through in silico rational design and systems engineering of disulfide bridges in the catalytic domain. Specifically, 7 residue pairs (P35-G426, Q107-G167, G116-Q120, A147-W160, G233-V265, A332-G370, and R436-M480) were chosen as engineering targets for disulfide bridge formation, and the respective residues were replaced with cysteines. Three single disulfide bridge mutants—P35C-G426C, G116C-Q120C, and R436C-M480C—of the 7 showed significantly enhanced thermostability. Combinational mutations were subsequently assessed, and the triple mutant P35C-G426C/G116C-Q120C/R436C-M480C showed a 6-fold increase in half-life at 60°C and a 5.2°C increase in melting temperature compared with the wild-type enzyme. Interestingly, other biochemical properties of this mutant also improved: the optimum temperature increased from 50°C to 55°C, the optimum pH shifted from 9.5 to 10.0, the stable pH range extended from 7.0 to 11.0 to 6.0 to 12.0, and the catalytic efficiency (k_cat/K_m) increased from 1.8 × 10⁴ to 2.4 × 10⁴ liters/g · min. The possible mechanism responsible for these improvements was explored through comparative analysis of the model structures of wild-type and mutant enzymes. The disulfide bridge engineering strategy used in this work may be applied to improve the thermostability of other industrial enzymes.     

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 properties of an α-amylase inhibitor from wheat

Four inhibitors of α-amylase (EC 3.2.1.1) were separated from an alcohol extract of wheat by ion-change chromatography on DE52-cellulose. One inhibitor, which showed the greatest specificity for human salivary amylase relative to human pancreatic amylase, has been purified by the following steps: (a) alcohol fractionation (60–90%) of water extract (b) ion-exchange chromatography on QAE-Sephadex A-50; (c) re-chromatography on DE52-cellulose and (d) gel filtration on Sephadex G-50. The purified inhibitor is 100 times more specific for human salivary amylase than for human pancreatic amylase. It shows an electrophoretic mobility of 0.2 on disc gel electrophoresis and a molecular weight of about 21 000. This inhibitor contributes about 16% to the total salivary amylase inhibiting power of the wheat extract.     

Structure-Guided Systems-Level Engineering of Oxidation-Prone Methionine Residues in Catalytic Domain of an Alkaline α-Amylase from Alkalimonas amylolytica for Significant Improvement of Both Oxidative Stability and Catalytic Efficiency

High oxidative stability and catalytic efficiency are required for the alkaline α-amylases to keep the enzymatic performance under the harsh conditions in detergent industries. In this work, we attempted to significantly improve both the oxidative stability and catalytic efficiency of an alkaline α-amylase from Alkalimonas amylolytica by engineering the five oxidation-prone methionine residues around the catalytic domain via a systematic approach. Specifically, based on the tertiary structure analysis, five methionines (Met 145, Met 214, Met 229, Met 247 and Met 317) were individually substituted with oxidation-resistant threonine, isoleucine and alaline, respectively. Among the created 15 mutants, 7 mutants M145A, M145I, M214A, M229A, M229T, M247T and M317I showed significantly enhanced oxidative stability or catalytic efficiency. In previous work, we found that the replacement of M247 with leucine could significantly improve the oxidative stability. Thus, these 8 positive mutants (M145A, M145I, M214A, M229A, M229T, M247T, M247L and M317I) were used to conduct the second round of combinational mutations. Among the constructed 85 mutants (25 two-point mutants, 36 three-point mutants, 16 four-point mutants and 8 five-point mutants), the mutant M145I-214A-229T-247T-317I showed a 5.4-fold increase in oxidative stability and a 3.0-fold increase in catalytic efficiency. Interestingly, the specific activity, alkaline stability and thermal stability of this mutant were also increased. The increase of salt bridge and hydrogen bonds around the catalytic domain contributed to the significantly improved catalytic efficiency and stability, as revealed by the three-dimensional structure model of wild-type alkaline α-amylase and its mutant M145I-214A-229T-247T-317I. With the significantly improved oxidative stability and catalytic efficiency, the mutant M145I-214A-229T-247T-317I has a great potential as a detergent additive, and this structure-guided systems engineering strategy may be useful for the protein engineering of the other microbial enzymes to fulfill industrial requirements.     

Identification of archaeon-producing hyperthermophilic α-amylase and characterization of the α-amylase

The extremely thermophilic anaerobic archaeon strain, HJ21, was isolated from a deep-sea hydrothermal vent, could produce hyperthermophilic alpha-amylase, and later was identified as Thermococcus from morphological, biochemical, and physiological characteristics and the 16S ribosomal RNA gene sequence. The extracellular thermostable alpha-amylase produced by strain HJ21 exhibited maximal activity at pH 5.0. The enzyme was stable in a broad pH range from pH 5.0 to 9.0. The optimal temperature of alpha-amylase was observed at 95 degrees C. The half-life of the enzyme was 5 h at 90 degrees C. Over 40% and 30% of the enzyme activity remained after incubation at 100 degrees C for 2 and 3 h, respectively. The enzyme did not require Ca(2+) for thermostability. This alpha-amylase gene was cloned, and its nucleotide sequence displayed an open reading frame of 1,374 bp, which encodes a protein of 457 amino acids. Analysis of the deduced amino acid sequence revealed that four homologous regions common in amylases were conserved in the HJ21 alpha-amylase. The molecular weight of the mature enzyme was calculated to be 51.4 kDa, which correlated well with the size of the purified enzyme as shown by the sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Hydrolysis of starches by the action of an α-amylase from Bacillus subtilis

A moderately thermophilic Bacillus subtilis strain, isolated from fresh sheep’s milk, produced extracellular thermostable α-amylase. Maximum amylase production was obtained at 40 °C in a medium containing low starch concentrations. The enzyme displayed maximal activity at 135 °C and pH 6.5 and its thermostability was enhanced in the presence of either calcium or starch. This thermostable α-amylase was used for the hydrolysis of various starches. An ammonium sulphate crude enzyme preparation as well as the cell-free supernatant efficiently degraded the starches tested. The use of the clear supernatant as enzyme source is highly advantageous mainly because it decreases the cost of the hydrolysis. Upon increase of reaction temperature to 70 °C, all substrates exhibited higher hydrolysis rates. Potato starch hydrolysis resulted in a higher yield of reducing sugars in comparison to the other starches at all temperatures tested. Soluble and rice starch took, respectively, the second and third position regarding reducing sugars liberation, while the α-amylase studied showed slightly lower affinity for corn starch and oat starch.     

Kinetics of improved production and thermostability of an intracellular β-glucosidase from a mutant-derivative of Cellulomonas biazotea

The highest productivity (20 IU l(-1) h(-1)) of beta-glucosidase by a mutant of Cellulomonas biazotea was 2.5-fold more than that of the parent organism. The enzyme had a lower activation energy (57 kJ mol(-1)) than the native enzyme (68 kJ mol(-1)). The enzyme from the mutant had enthalpy and entropy values for irreversible intactivation of 95.6 kJ mol(-1) and 60 J.mol(-1) K(-1) compared with 108 kJ mol(-1) and 86 J mol(-1) K(-1) for the native enzyme suggesting that the mutation had stabilized the enzyme.     

Immobilization of the α-amylase of Bacillus amyloliquifaciens TSWK1-1 for the improved biocatalytic properties and solvent tolerance

The α-amylase of Bacillus amyloliquifaciens TSWK1-1 (GenBank Number, GQ121033) was immobilized by various methods, including ionic binding with DEAE cellulose, covalent coupling with gelatin and entrapment in polyacrylamide and agar. The immobilization of the purified enzyme was most effective with the DEAE cellulose followed by gelatin, agar and polyacrylamide. The K _m increased, while V _max decreased upon immobilization on various supports. The temperature and pH profiles broadened, while thermostability and pH stability enhanced after immobilization. The immobilized enzyme exhibited greater activity in various non-ionic surfactants, such as Tween-20, Tween-80 and Triton X-100 and ionic surfactant, SDS. Similarly, the enhanced stability of the immobilized α-amylase in various organic solvents was among the attractive features of the study. The reusability of the immobilized enzyme in terms of operational stability was assessed. The DEAE cellulose immobilized α-amylase retained its initial activity even after 20 consequent cycles. The DEAE cellulose immobilized enzyme hydrolyzed starch with 27 % of efficiency. In summary, the immobilization of B. amyloliquifaciens TSWK1-1 α-amylase with DEAE cellulose appeared most suitable for the improved biocatalytic properties and stability.     

Glutamic acid 219 is critical for the thermostability of a truncated α-amylase from alkaliphilic and thermophilic Bacillus sp. strain TS-23

The functional and structural significance of glutamic acid 219 of a N- and C-terminally truncated Bacillus sp. strain TS-23 α-amylase (BACΔNC) was explored by the approach of site-directed saturation mutagenesis. The expressed wild-type and mutant enzymes have been purified by nickel-chelate chromatography and their molecular mass was determined to be approximately 54 kDa by SDS/PAGE. Except E219F, E219P, and E219W, all other mutant enzymes exhibited a lower shift in their optimum temperatures with respect to the wild-type enzyme. A decreased thermostability was also found in all of the mutant enzymes when compared with the wild-type form of BACΔNC. Except E219F, E219P, and E219W mutant enzymes, greater than 2-fold decrease in k _cat and a similar substrate affinity relative to the wild-type BACΔNC were observed for the rest mutant enzymes. Based on these observations, it is suggested that Glu-219 apparently plays an important role in the thermostability of BACΔNC.     

Characterization of an exo-acting intracellular α-amylase from the hyperthermophilic bacterium Thermotoga neapolitana

We cloned and expressed the gene for an intracellular α-amylase, designated AmyB, from the hyperthermophilic bacterium Thermotoga neapolitana in Escherichia coli. The putative intracellular amylolytic enzyme contained four regions that are highly conserved among glycoside hydrolase family (GH) 13 α-amylases. AmyB exhibited maximum activity at pH 6.5 and 75°C, and its thermostability was slightly enhanced by Ca²⁺. However, Ca²⁺ was not required for the activity of AmyB as EDTA had no effect on enzyme activity. AmyB hydrolyzed the typical substrates for α-amylase, including soluble starch, amylose, amylopectin, and glycogen, to liberate maltose and minor amount of glucose. The hydrolytic pattern of AmyB is most similar to those of maltogenic amylases (EC 3.2.1.133) among GH 13 α-amylases; however, it can be distinguished by its inability to hydrolyze pullulan and β-cyclodextrin. AmyB enzymatic activity was negligible when acarbose, a maltotetraose analog in which a maltose residue at the nonreducing end was replaced by acarviosine, was present, indicating that AmyB cleaves maltose units from the nonreducing end of maltooligosaccharides. These results indicate that AmyB is a new type exo-acting intracellular α-amylase possessing distinct characteristics that distinguish it from typical α-amylase and cyclodextrin-/pullulan-hydrolyzing enzymes.     

Molecular basis for the specific binding of different α-amylase inhibitors from Phaseolus vulgaris seeds to the active site of α-amylase

In search of a possible mechanism of inhibition which might be responsible for the different specificities of the three isoforms of the bean (Phaseolus vulgaris) α-amylase inhibitor α-AI1, α-AI2 and α-AIL (EC 3.2.1.1), the two isoforms α-AI2 and α-AIL were modelled from the atomic co-ordinates of α-AI1 in the α-AI1/PPA complex and docking experiments were performed with pig pancreatic α-amylase (PPA) and the modelled amylase from Zabrotes subfasciatus (ZSA). The modelled α-AI2 penetrates without any steric hindrance in the substrate cleft of both enzymes but the possible hydrogen bonds between PPA and α-AI2 seem too few to maintain the stability of the complex. α-AIL, which differs from α-AI1 and α-AI2 by the absence of post-translational proteolytic cleavage and the occurrence of two additional loops of fifteen and six residues, creates steric clashes with PPA and ZSA that prevent its penetration into the substrate cleft of the enzyme. Docking experiments explain at the molecular level the specificity of α-amylase inhibitor isoforms towards enzymes of different origins. In addition, they explain why, according to its unprocessed and more bulky character, α-AIL was previously shown to be inactive on all α-amylases assayed. In fact, this last isoform is now considered as an evolutionary intermediate between phytohaemagglutinins, arcelins and α-amylase inhibitors.     

Probing the role of asparagine mutation in thermostability of Bacillus KR-8104 α-amylase

Asparagine deamidation is one of the important determinants of protein thermostability. Here, structure based mutagenesis has been done in order to probe the role of Asn residues in thermostability of a Ca independent Bacillus sp. KR-8104 α-amylase (BKA). Residues involved in potential deamidation processes have been selected and replaced using a site directed mutagenesis. Fourteen different variants were tested for thermostability by measuring residual activities after incubation at high temperature. In comparison to the wild-type enzyme, four mutated variants are able to increase the half life of the protein at high temperatures. The highest stabilization resulted from the substitution of asparatate in place of asparagine at position 112, leading to a nearly fivefold increase of the enzyme's half-life at 70°C. Also replacement of Asn129 to aspartic acid and Asn312 to serine markedly increased the half-life of the enzyme at 70°C indicating that the deamination of these residues may have a deleterious effect on BKA.     

Conditions for the overproduction and excretion of thermostable α-amylase and pullulanase from Clostridium thermohydrosulfuricum DSM 567

Summary Conditions in continuous culture were identified under which thermostable -amylase and pullulanase were overproduced and excreted by Clostridium thermohydrosulfuricum DSM 567. Maximal amounts of these enzymes were formed at a dilution rate of 0.05/h at pH of 6.5 and under starch limitation. Unlike the results obtained in batch culture, more than 90% of the enzymes were released into the culture fluid. In addition, the concentration of these enzymes was raised 50- to 100-fold. A shift in fermentation products (more lactate and less acetate production) was observed, when the concentration of ferrous ions in the medium was decreased from 23 M to 6.5 M.     

Effect of temperature on some characteristics of the thermostable α-amylase from Bacillus licheniformis

The V _max of an extracellular, thermostable -amylase from Bacillus licheniformis 44MB82 were 5.70×10^-3 and 9.70×10^-3 mM s^-1 at 30 and 90°C, respectively, whereas the K _m values were similar (0.9 mg ml^-1) at both temperatures. Excluding dextrins, the dominant products from soluble starch and amylopectin hydrolysis contained less than six glucose residues. The enzyme hydrolysed amylopectin better than soluble starch. Increasing the temperature from 30 to 90°C was accompanied by an increase in the production of malto-oligosaccharides, especially maltotetrose, and this was related to the secondary hydrolysis of maltopentose and maltohexose.The authors are with the Institute of Microbiology, Bulgarian Academy of Sciences, Sofia 1113. 26 Academician G. Bonchev, Bulgaria     

Characterization and application of a detergent-stable alkaline α-amylase from Bacillus subtilis strain AS-S01a

A strain AS-S01a, capable of producing high-titer alkaline α-amylase, was isolated from a soil sample of Assam, India and was taxonomically identified as Bacillus subtilis strain AS-S01a. Optimized α-amylase yield by response surface method (RSM) was obtained as 799.0 U with a specific activity of 201.0 U/mg in a process control bioreactor. A 21.0 kDa alkaline α-amylase purified from this strain showed optimum activity at 55 °C and pH 9.0, and it produced high molecular weight oligosaccharides including small amount of glucose from starch as the end product. The K_m and V_max values for this enzyme towards starch were determined as 1.9 mg/ml and 198.21 μmol/min/mg, respectively. The purified α-amylase retained its activity in presence of oxidant, surfactants, EDTA and various commercial laundry detergents, thus advocating its suitability for various industrial applications.     

Characteristics of an aqueous two-phase system for α-amylase production

The characteristics of an aqueous two-phase system for the overproduction of extracellular enzyme through α-amylase fermentation by Bacillus amyloliquefaciens were investigated. With higher molecular weight of polyethylene glycol (PEG) or lower molecular weight of dextran, the partition coefficient of α-amylase was increased. α-Amylase biosynthesis was increased when PEG 6000 was included in the medium compared to the medium without PEG. Phosphate addition to the PEG-dextran system improved the partition coefficient of α-amylase, but deactivated α-amylase severely. By using sodium sulfate instead of phosphate, α-amylase deactivation was negligible, and high partitioning of the enzyme in the top phase was obtained.