Extensive hydrolysis of raw rice starch by a chimeric α-amylase engineered with α-amylase (AmyP) and a starch-binding domain from Cryptococcus sp. S-2

Recombinant chimeric α-amylase (AmyP-Cr) was constructed by a catalytic core of α-amylase (AmyP) from a marine metagenomic library and a starch-binding domain (SBD_Cr) of α-amylase from Cryptococcus sp. S-2. The molecular fusion did not alter optimum pH, optimum temperature, hydrolysis products, and an ability of preferential and rapid degradation towards raw rice starch, but catalytic efficiency and thermostability were remarkably improved compared with those of the wild-type AmyP. AmyP-Cr achieved the final hydrolysis degree of 61.7 ± 1.2% for 10% raw rice starch and 47.3 ± 0.8% for 15% raw rice starch after 4 h at 40 °C with 1.0 U per mg of raw starch. The catalytic efficiency was very high, with 3.6–4.0 times higher than that of AmyP. The enhanced catalytic efficiency was attributed to the better thermostability and the higher adsorption and disruption to raw rice starch caused by SBD_Cr. The properties of AmyP-Cr open a new way in terms of a new design of raw rice starch processing.

     

Corn porous starch: preparation, characterization and adsorption property

This study was carried out to develop a new type of modified starch based on α-amylase and glucoamylase. The structural and chemical characteristics of the porous starch were determined by Fourier-transform infrared (FTIR) spectroscopy, scanning electron microscopy (SEM), X-ray diffraction (XRD) and differential scanning calorimetry (DSC). The potential application of the porous starch as an adsorbent was evaluated using methyl violet as an adsorbed model. The adsorption capacity was optimized by investigating the reaction factors, including the mass ratio of α-amylase to glucoamylase (m_α-amylase/m_glucoamylase), the mass ratio of total amount of enzymes to starch (m_enzyme/m_St), the ratio of liquid volume to starch mass (VH₂O/mSt), pH value of the reaction solution, enzymatic reaction temperature, and enzymatic reaction time. The hydrolysis ratio of each sample was also determined to investigate the effect of different reaction conditions on the hydrolysis degree. The results suggest that the porous starch has a more excellent adsorption capacity than the native starch, and may be expected to have wide potential applications in many fields.     

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.     

Production,Purification, and Characterization of α-Amylase from Solventogenic Clostridium sp. BOH3

A solventogenic strain of Clostridium sp. BOH3 produces extracellular α-amylase (7.15 U/mg protein) in reinforced clostridial medium supplemented with sugarcane bagasse hydrolysate (1 % w/v) and a small amount of starch (0.1 % w/v), which is essential for the expression of α-amylase. In the presence of α-amylase, BOH3 utilizes starch directly without any pretreatment and produces butanol almost equivalent (～90 %) to the production of butanol from glucose. α-Amylase can be purified from culture supernatant by using one-step weak anion exchange chromatography with a yield of 43 %. In peptide fingerprinting analysis, this enzyme shows homology with α-amylase produced by Clostridium acetobutylicum ATCC824. However, the molecular weight is 54 kDa, which is smaller than α-amylase of ATCC824 (84 kDa). This enzyme has optimum temperature at 45–50 °C and optimum pH at 4.5–5.5. Under this condition, the enzyme activity is 91.32 U/mg protein, and its K _m and V _max values are 1.71?±?0.02 mg/ml and 96.13?±?0.15 μmol/min/mg protein, respectively. Activity of this α-amylase can be enhanced (>1.5 times) by addition of Ca²⁺ and Co²⁺ and its activity can be maintained at an acidic pH (pH 3–5) for about 24 h. These unique characteristics suggest that this enzyme can be used for saccharification of starch for production of biofuel in one pot.     

Effects of Pulsed Electric Field (PEF) Treatment on Enhancing Activity and Conformation of α-Amylase

To explore an efficient, safe, and speedy application of pulsed electric field (PEF) technology for enzymatic modification, effects of PEF treatment on the enzymatic activity, property and kinetic parameters of α-amylase were investigated. Conformational transitions were also studied with the aid of circular dichroism (CD) and fluorescence spectra. The maximum enzymatic activity of α-amylase was obtained under 15 kV/cm electric field intensity and 100 mL/min flow velocity PEF treatment, in which the enzymatic activity increased by 22.13 ± 1.14 % compared with control. The activation effect could last for 18 h at 4 °C. PEF treatment could widen the range of optimum temperature for α-amylase, however, it barely exerted any effect on the optimum pH. On the other hand, α-amylase treated by PEF showed an increase of V _max, t_1/2 and ΔG, whereas a decrease of K _m and k were observed. Furthermore, it can be observed from fluorescence and CD spectra that PEF treatment had increased the number of amino acid residues, especially that of tryptophan, on α-amylase surface with enhanced α-helices by 34.76 % and decreased random coil by 12.04 % on α-amylase when compared with that of untreated. These changes in structure had positive effect on enhancing α-amylase activity and property.     

Engineering of Barley α-Amylase

Abstract

Protein engineering of barley α-amylase addressed the roles of Ca²⁺ in activity and inhibition by barley α-amylase/subtilisin inhibitor (BASI), multiple attach in polysaccharide hydrolysis, secondary starch binding sites, and BASI hot spots in AMY2 recognition. AMY1/AMY2 isozyme chimeras faciliatated assignment of function to specific regions of the structure. An AMY1 fusion with starch binding domain and AMY1 mutants in the substrate binding cleft gave degree of multiple attack of 0.9–3.3, compared to 1.9 for wild-type. About 40% of the secondary attacks, succeeding the initial endo-attack, produced DP5-10 maltooligosaccharides in similar proportion for all enzyme variants, whereas shorter products, comprising about 25%, varied depending on the mutation. Secondary binding sites were important in both multiple attack and starch granule hydrolysis. Surface plasmon resonance and inhibition analyses indicated the importance of fully hydrated Ca²⁺ at the AMY2/BASI interface to strengthen the complex. Engineering of intermolecular contacts in BASI modulated the affinity for AMY2 and the target enzyme specificity.     

The surface structure of a complex substrate revealed by enzyme kinetics and Freundlich constants for α-amylase interaction with the surface of starch

Background

Starch is a main source of carbohydrate in human diets, but differences are observed in postprandial glycaemia following ingestion of different foods containing identical starch contents. Such differences reflect variations in rates at which different starches are digested in the intestine. In seeking explanations for these differences, we have studied the interaction of α-amylase with starch granules. Understanding this key step in digestion should help with a molecular understanding for observed differences in starch digestion rates.

Methods

For enzymes acting upon solid substrates, a Freundlich equation relates reaction rate to enzyme adsorption at the surface. The Freundlich exponent (n) equals 2/3 for a liquid-smooth surface interface, 1/3 for adsorption to exposed edges of ordered structures and 1.0 for solution–solution interfaces. The topography of a number of different starch granules, revealed by Freundlich exponents, was compared with structural data obtained by differential scanning calorimetry and Fourier transform infrared spectroscopy with attenuated total internal reflectance (FTIR-ATR).

Results

Enzyme binding rate and FTIR-ATR peak ratio were directly proportional to n and Δ_gelH was inversely related to n. Amylase binds fastest to solubilised starch and to granules possessing smooth surfaces at the solid–liquid interface and slowest to granules possessing ordered crystalline surfaces.

Conclusions

Freundlich exponents provide information about surface blocklet structures of starch that supplements knowledge obtained from physical methods.

General Significance

Nanoscale structures at the surface of starch granules influence hydrolysis by α-amylase. This can be important in understanding how dietary starch is digested with relevance to diabetes, cardiovascular health and cancer.     

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.     

Biochemical Studies on Ricin Part X Effect of the Two Constituent Polypeptide Chains of Ricin D toward Mouse Sarcoma Ascite Tumor Cells

A maltotetraose-forming amylase from Pseudomonas stutzeri was highly purified by adsorption on starch granules and by chromatographies on Sephadex G-100 and DEAE-cellulose. The purified enzyme showed a single band in polyacrylamide gel electrophoreses with or without sodium dodecylsulfate. The optimum pH for enzyme action on starch was 6.0-6.5, and the optimum temperature was 45°C. The purified enzyme attacked starch from the non-reducing end to produce α-anomer oligosaccharides. This indicated that the enzyme was an exo-α-amylase which had not hitherto been found. The enzyme activity was markedly inhibited by the addition of Cu²⁺, Hg²⁺, N-bromosuccinimide and 2,3-butanedione. The molecular weight of the enzyme determined by the method of Weber and Osborn was about 5.7 × 10⁴. The isoelectric point of the enzyme was estimated to be 5.3 by polyacrylamide gel electrofocusing. The Km and k₀ values of this enzyme for starch, glycogen, short chain amylose and some maltooligosaccharides were calculated from Lineweaver-Burk plots.     

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.     

Identification and biochemical characterisation of α-amylase in the alimentary tract of Mediterranean fruit fly,Ceratitis capitata (Wiedemann) (Diptera: Tephritidae)

Mediterranean fruit fly (Medfly), Ceratitis capitata, is an important pest of many fruit crops in temperate and subtropical regions worldwide. α-Amylases are hydrolytic enzymes involved in carbohydrate metabolism in insects. There is no report about α-amylase activity in C. capitata in literature. So, the aim of the current study was biochemical characterisation of α-amylase in the alimentary canal of the pest to gain a better understanding of digestive physiology of the insect. α-Amylase of Medfly was extracted and characterised using starch as the substrate. The results showed the presence of α-amylase activity in the gut of the insect for carbohydrate digestion. Optimum activity of the enzyme occurs at pH 8.0 and 40?°C. The most effective activator of the enzyme was determined in treatment with 20?mM CaCl₂. Na⁺, K⁺ and Mg²⁺ ions also activated the enzyme. Native PAGE of α-amylase showed two isoenzymes suggesting the importance of α-amylase in the carbohydrate digestion in the insect. Understanding of the digestive physiology and α-amylase activity of Medfly is important when new management strategies for this economically important pest are devised.     

Kinetics and thermodynamics of catalysis and thermal inactivation of a novel α-amylase (Tp-AmyS) from Thermotoga petrophila

Abstract

This research is focussed on kinetic, thermodynamic and thermal inactivation of a novel thermostable recombinant α-amylase (Tp-AmyS) from Thermotoga petrophila. The amylase gene was cloned in pHIS-parallel1 expression vector and overexpressed in Escherichia coli. The steady-state kinetic parameters (V_max, K_m, k_cat and k_cat/K_m) for the hydrolysis of amylose (1.39?mg/min, 0.57?mg, 148.6?s^?1, 260.7), amylopectin (2.3?mg/min, 1.09?mg, 247.1?s^?1, 226.7), soluble starch (2.67?mg/min, 2.98?mg, 284.2?s^?1, 95.4) and raw starch (2.1?mg/min, 3.6?mg, 224.7?s^?1, 61.9) were determined. The activation energy (E_a), free energy (ΔG), enthalpy (ΔH) and entropy of activation (ΔS) at 98?°C were 42.9?kJ mol^?1, 74?kJ mol^?1, 39.9?kJ mol^?1 and ?92.3 J mol^?1 K^?1, respectively, for soluble starch hydrolysis. While ΔG of substrate binding (ΔG_E-S) and ΔG of transition state binding (ΔG_E-T) were 3.38 and ?14.1?kJ mol^?1, respectively. Whereas, EaD, Gibbs free energy (ΔG*), increase in the enthalpy (ΔH*) and activation entropy (ΔS*) for activation of the unfolding of transition state were 108, 107, 105?kJ mol^?1 and ?4.1 J mol^?1 K^?1. The thermodynamics of irreversible thermal inactivation of Tp-AmyS revealed that at high temperature the process involves the aggregation of the protein.     

Cloning and overexpression of raw starch digesting α-amylase gene from Bacillus subtilis strain AS01a in Escherichia coli and application of the purified recombinant α-amylase (AmyBS-I) in raw starch digestion and baking industry

Considering the economic and industrial relevance of α-amylases used in food and starch industries, a raw starch digesting α-amylase gene (amyBS-I) from Bacillus subtilis strain AS01a was cloned and expressed in Escherichia coli BL21 cells. The gene also includes its signal peptide sequence (SPS) for facilitating the efficient extracellular expression of recombinant α-amylase (AmyBS-I) in correctly folded (enzymatically active) form. The native AmyBS-I consists of 659 amino acids with a molecular mass and pI of 72,387 Da and 5.8, respectively. The extracellular secretion of AmyBS-I after response surface optimization of culture conditions was found to be 7-fold higher as compared to its production under non-optimized conditions. Purified AmyBS-I demonstrated optimum activity at 70 °C and pH 6.0. It shows K_m and V_max values toward soluble starch as 2.7 mg/ml and 454 U/ml, respectively. Further, it does not require Ca²⁺ ion for its α-amylase activity/thermo-stability, which is an added advantage for its use in the starch industry. The AmyBS-I also hydrolyzed a wide variety of raw starches and produced maltose and glucose as main hydrolyzed products. The bread dough supplemented with AmyBS-I showed better amelioration of the bread quality as compared to the bread supplemented with commercial α-amylase.     

Digestive amylase and pectinase activity in the larvae of alfalfa weevil Hypera postica (Coleoptera: Curculionidae)

The alfalfa weevil Hypera postica is a serious economic pest in most alfalfa grown in many countries worldwide. Digestive α-amylase and pectinase activities of larvae were investigated using general substrates. Midgut extracts from larvae showed an optimum activity for α-amylase against starch at acidic pH (pH 5.0). α-Amylase from larval midgut was more stable at mildly acidic pH (pH 5–6) than highly acidic and alkaline pH. The enzyme showed its maximum activity at 35°C. α-Amylase activity was significantly decreased in the presence of Ca²⁺, Mg²⁺ and sodium dodecylsulfate. On the contrary, K⁺ and Na⁺ did not significantly affect the enzyme activity. Zymogram analysis revealed the presence of one band of α-amylase activity in in-gel assays. Pectinase activity was assayed using agarose plate and colorimetric assays. Optimal pH for pectinase activity in the larval midgut was determined to be pH 5.0. Pectinase enzyme is more stable at pH 4.0–7.0 than highly acidic and alkaline pH. However, the enzyme was more stable at slightly acidic pH (pH 6.0) when incubation time increased. Maximum activity for the enzyme incubated at different temperatures was observed to be 40°C. Optimum pH activity for α-amylase and pectinase is not completely consistent with the pH prevailing in the larval midgut. This is the first report of the presence of pectinase activity in H. postica.     

Glycosylated salivary α-amylases are capable of maltotriose hydrolysis and glucose formation

The physiological and/or clinical significance of sugar chains in human salivary αamylase was investigated in terms of substrate-specificity for synthesized malto-oligosaccharides. Glycosylated and non-glycosylated α-amylases were prepared on a Sephacryl S-200 column, in which the amylases were separated into four fractions from the different affinities for Sephacryl: fraction I, amylases bearing sugar chains with sialic acid; fraction II, amylases bearing sugar chains without sialic acid; fractions III and IV, non-glycosylated amylases. These were classified according to the differences in their affinities for lectins, molecular sizes and isoelectric points. The inhibitory effect of maltotriose (G₃) on starch hydrolysis of the amylase fraction, suggests that starch and G₃ can be the substrate for glycosylated amylase, and that the glycosylated amylases are capable of G₃ hydrolysis for conversion into maltose and glucose. Using malto-oligosaccharides, G₃, G₄, G₅ and G₇, as substrates, the substrate-specificities and G₃/G₅ ratio of amylase activities in the four fractions were examined. Maltopentaose, G₅, is routinely used as a substrate for α-amylase, and then we assumed that both glycosylated and non-glycosylated amylases react with G₅. Moreover, the results indicate that the glycosylated amylases clearly had a higher capacity for G₃ hydrolysis than the non-glycosylated amylases, although no substrate preference of either type of amylase was observed among G₄, G₅ and G₇. Glycosylated amylases have the capacity for glucose formation from malto-oligosaccharides.     

Biochemical characterisation of digestive α-amylase of Red Palm Weevil,Rhynchophorus ferrugineus (Olivier, 1790) (Coleoptera: Curculionidae)

The Red Palm Weevil, Rhynchophorus ferrugineus (Oliver) (Coleoptera: Curculionidae), is a serious pest of a wide range of plant species including coconut, sago, date and oil palms. The α-amylases are the hydrolytic enzymes that are involved in carbohydrate metabolism in insects. So far nothing is done to demonstrate α-amylase activity of R. ferrugineus. Thus, the aim of the current study was to identify and characterise the α-amylase activity to gain a better understanding of digestive physiology of the insect. Thus, the α-amylase in the gut of red palm weevil was isolated and characterised using starch as a substrate. The study showed that the α-amylase is present in the gut of the insect for carbohydrate digestion. The α-amylase has an optimum pH and temperature of 5 and 40°C. The activity of α-amylase was increased by NaCl and KCl and inhibited by other compounds such as MgCl₂, CaCl₂, urea, ethylenediaminetetraacetic acid and sodium dodecylsulfate. Native-PAGE electrophoresis of α-amylase showed two isoenzymes, one major and one minor band showing α-amylase importance in the carbohydrate metabolism of the insect. Understanding of the digestive physiology and α-amylase activity of Red Palm Weevil is important when new management strategies for this economically important pest are devised.     

α-Amylase from germinating soybean (Glycine max) seeds – Purification,characterization and sequential similarity of conserved and catalytic amino acid residues

Starch hydrolyzing amylase from germinated soybeans seeds (Glycine max) has been purified 400-fold to electrophoretic homogeneity with a final specific activity of 384 units/mg. SDS–PAGE of the final preparation revealed a single protein band of 100 kDa, whereas molecular mass was determined to be 84 kDa by MALDI–TOF and gel filtration on Superdex-200 (FPLC). The enzyme exhibited maximum activity at pH 5.5 and a pI value of 4.85. The energy of activation was determined to be 6.09 kcal/mol in the temperature range 25–85 °C. Apparent Michaelis constant (K_m(app)) for starch was 0.71 mg/mL and turnover number (k_cat) was 280 s^?1 in 50 mM sodium acetate buffer, pH 5.5. Thermal inactivation studies at 85 °C showed first-order kinetics with rate constant (k) equal to 0.0063 min^?1. Soybean α-amylase showed high specificity for its primary substrate starch. High similarity of soybean α-amylase with known amylases suggests that this α-amylase belongs to glycosyl hydrolase family 13. Cereal α-amylases have gained importance due to their compatibility for biotechnological applications. Wide availability and easy purification protocol make soybean as an attractive alternative for plant α-amylase. Soybean can be used as commercially viable source of α-amylase for various industrial applications.     

Domain C of thermostable α-amylase of Geobacillus thermoleovorans mediates raw starch adsorption

The gene (1,542 bp) encoding thermostable Ca²⁺-independent and raw starch hydrolyzing α-amylase of the extremely thermophilic bacterium Geobacillus thermoleovorans encodes for a protein of 50 kDa (Gt-amyII) with 488 amino acids. The enzyme is optimally active at pH 7.0 and 60 °C with a t _1/2 of 19.4 h at 60 and 4 h at 70 °C. Gt-amyII hydrolyses corn and tapioca raw starches efficiently and therefore finds application in starch saccharification at industrial sub-gelatinisation temperatures. The starch hydrolysis is facilitated following adsorption of the enzyme to starch at the C-terminal domain, as confirmed by the truncation analysis. The adsorption rate constant of Gt-amyII to raw corn starch is 37.6-fold greater than that for the C-terminus truncated enzyme (Gt-amyII-T). Langmuir–Hinshelwood kinetic analysis in terms of equilibrium parameter (K _R) suggested that the adsorption of Gt-amyII to corn starch is more favourable than that of Gt-amyII-T. Thermodynamics of temperature inactivation indicated a decrease in thermostabilisation of Gt-amyII upon truncation of its C-terminus. The addition of raw corn starch increased t _1/2 of Gt-amyII, but it has no such effect on Gt-amyII-T. It can, therefore, be stated that Gt-amyII binds to raw corn starch via C-terminal region that contributes to its thermostability. Phylogenetic analysis confirmed that starch binding region of Gt-amyII is, in fact, the non-catalytic domain C, and not the typical SBD of CBM families. The role of domain C in raw starch binding throws light on the evolutionary path of the known SBDs.     

Effect of aluminium on metabolism of starch and sugars in growing rice seedlings

The effect of increasing concentrations of Al₂(SO₄)₃ in situ on the content of starch, sugars and activity behaviour of enzymes related to their metabolism were studied in growing seedlings of two rice cvs. Malviya-36 and Pant-12 in sand cultures. Al₂(SO₄)₃ levels of 80 and 160 μM in the growth medium caused an increase in the contents of starch, total sugars as well as reducing sugars in roots as well as shoots of the rice seedlings during a 5–20 days growth period. The activities of the enzymes of starch hydrolysis α-amylase, β-amylase and starch phosphorylase declined in Al-exposed seedlings, whereas the activities of sucrose hydrolyzing enzymes sucrose synthase and acid invertase increased in the seedlings due to Al³⁺ treatment. The enzyme of sucrose synthesis, sucrose phosphate synthase showed decreased activity in Al³⁺ treated seedlings compared to controls. Results suggest that Al³⁺ toxicity in rice seedlings impairs the metabolism of starch and sugars and favours the accumulation of hexoses by enhancing the activities of sucrose hydrolyzing enzymes.     

Purification and characterization of a maltooligosaccharide-forming α-amylase from a new Bacillus subtilis KCC103

A maltooligosaccharide-forming α-amylase was produced by a new soil isolate Bacillus subtilis KCC103. In contrast to other Bacillus species, the synthesis of α-amylase in KCC103 was not catabolite-repressed. The α-amylase was purified in one step using anion exchange chromatography after concentration of crude enzyme by acetone precipitation. The purified α-amylase had a molecular mass of 53 kDa. It was highly active over a broad pH range from 5 to 7 and stable in a wide pH range between 4 and 9. Though optimum temperature was 65–70 °C, it was rapidly deactivated at 70 °C with a half-life of 7 min and at 50 °C, the half-life was 94 min. The K _m and V _max for starch hydrolysis were 2.6 mg ml⁻¹ and 909 U mg⁻¹, respectively. Ca²⁺ did not enhance the activity and stability of the enzyme; however, EDTA (50 mM) abolished 50% of the activity. Hg²⁺, Ag²⁺, and p-hydroxymercurybenzoate severely inhibited the activity indicating the role of sulfydryl group in catalysis. The α-amylase displayed endolytic activity and formed maltooligosaccharides on hydrolysis of soluble starch at pH 4 and 7. Small maltooligosaccharides (D2–D4) were formed more predominantly than larger maltooligosaccharides (D5–D7). This maltooligosaccharide forming endo-α-amylase is useful in bread making as an antistaling agent and it can be produced economically using low-cost sugarcane bagasse.