An object is to obtain a β-amylase having heat resistance even to high temperatures exceeding 60° C. By screening β-amylase producing bacteria from a soil sample, a novel Bacillus halosaccharovorans strain having a novel β-amylase with heat resistance and the β-amylase from the novel B. halosaccharovorans strain were obtained.

An object is to obtain a β-amylase having heat resistance even to high temperatures exceeding 60° C. By screening β-amylase producing bacteria from a soil sample, a novel Bacillus halosaccharovorans strain having a novel β-amylase with heat resistance and the β-amylase from the novel B. halosaccharovorans strain were obtained.

This specification discloses process for obtaining maltodextrin having DE between 17 and 19.9 and the maltodextrins obtained from the process. The disclosed maltodextrins can be provided as a powder or in shelf stable liquid form. The disclose maltodextrins have a polysaccharide profile similar to those observed for prior art maltodextrins, but make maltodextrin solutions having a high solids content, but reduced viscosity compared to prior art maltodextrins, on equivalent solids-in-solution basis. The process combines adds an alpha-amylase and a pullulanase enzyme to a polysaccharide mixture during a saccharification step. The disclosed maltodextrins make solutions at 50° C. and greater than 65% on a solids dry solids basis having a viscosity between 5,000 and 12,000 cP and having a water activity of less than 0.80.

This specification discloses process for obtaining maltodextrin having DE between 17 and 19.9 and the maltodextrins obtained from the process. The disclosed maltodextrins can be provided as a powder or in shelf stable liquid form. The disclose maltodextrins have a polysaccharide profile similar to those observed for prior art maltodextrins, but make maltodextrin solutions having a high solids content, but reduced viscosity compared to prior art maltodextrins, on equivalent solids-in-solution basis. The process combines adds an alpha-amylase and a pullulanase enzyme to a polysaccharide mixture during a saccharification step. The disclosed maltodextrins make solutions at 50° C. and greater than 65% on a solids dry solids basis having a viscosity between 5,000 and 12,000 cP and having a water activity of less than 0.80.

An isoamylase having improved heat resistance and an industrial method for producing maltose from starch.

The isoamylase is an isoamylase consisting of the amino acid sequence represented by SEQ ID NO: 1 or an isoamylase resulting from deletion, substitution, or insertion of one to several amino acid residues in the amino acid sequence represented by SEQ ID NO: 1, wherein at least valine at amino acid number 515 and methionine at amino acid number 570 are mutated to other amino acids.

An isoamylase having improved heat resistance and an industrial method for producing maltose from starch.

The isoamylase is an isoamylase consisting of the amino acid sequence represented by SEQ ID NO: 1 or an isoamylase resulting from deletion, substitution, or insertion of one to several amino acid residues in the amino acid sequence represented by SEQ ID NO: 1, wherein at least valine at amino acid number 515 and methionine at amino acid number 570 are mutated to other amino acids.

The present invention provides a method for producing dietary fiber that has a mild sweet taste by reducing sugars and provides by-products having high added values, and dietary fiber produced by the method. The dietary fiber may be produced by including: liquefying roasted dextrin; and adding enzymes including α-amylase, β-amylase, and maltogenic amylase to the liquefied roasted dextrin, and saccharifying the same.

The present invention provides a method for producing dietary fiber that has a mild sweet taste by reducing sugars and provides by-products having high added values, and dietary fiber produced by the method. The dietary fiber may be produced by including: liquefying roasted dextrin; and adding enzymes including α-amylase, β-amylase, and maltogenic amylase to the liquefied roasted dextrin, and saccharifying the same.

A method for preparing a modified starch as an alternative to hydroxypropyl distarch phosphate, including: (a) evenly mixing a cassava starch with a buffer solution to obtain a starch suspension with desired pH; (b) adding α-amylase into the starch suspension for enzymolysis of glycosidic bonds followed by deactivation to obtain a first enzymolysis product; (c) adding hexose oxidase into the first enzymolysis product for lactonization of gluco-oligosaccharides followed by deactivation to obtain a second enzymolysis product; and (d) subjecting the second enzymolysis product to centrifugation, washing and freeze drying to obtain an enzymatically-modified cassava starch.

Green preparation methods of rice resistant starch are disclosed. In some embodiments, a green preparation method of the rice resistant starch is characterized in that, at a temperature lower than the gelatinization temperature, the rice starch is sequentially modified by enzymes using β-amylase, glucosidase, and pullulanase to obtain the modified starch. In other embodiments, a green preparation method of the rice resistant starch is characterized by using: rice starch as a substrate; and in turn using: (a) β-amylase (BA, EC 3.2.1.2) from barley (Hordeum vulgare); (b) glucoside transferase (TG, EC 2.4.1.24) from Aspergillus niger; and (c) pullulanase (PUL, EC 3.2.1.41) from Pullulanibacillus konaensis below a gelatinization temperature to modify a chain structure of the rice starch, resulting in a number of short linear chains which are effectively arranged, aggregated, and recrystallized at 4° C. to form modified rice starch with high resistant starch content.