Glucanase

The secondary and tertiary structures of β-glucanases involves the stacking of multiple β-sheets, each of which are made of several anti-parallel strands that bend and form a cleft crossing the active site of the enzyme.^[1] This type of structure has been called the "jelly roll fold."

• 1,3-β-glucanases (laminarinases, EC 3.2.1.39)^[1]
• Endo-1,3(4)-β-glucanase
• β-1,3-glucanase, an enzyme in plants that breaks down β-1,3-glucans such as callose or curdlan
• β-1,6 glucanase, an enzyme that breaks down β-1,6-glucans
• Cellulase, an enzyme that perform the hydrolysis of 1,4-beta-D-glycosidic linkages in cellulose, lichenin and cereal β-D-glucans.^[2]
• Xyloglucan-specific endo-beta-1,4-glucanase
• Xyloglucan-specific exo-beta-1,4-glucanase

• α-1,4-glucanase, an enzyme that breaks down α-1,4-glucans
• α-1,6-glucanase, an enzyme that breaks down α-1,6-glucans
• Pullulanase, a specific kind of glucanase that degrade pullulan

The functional formation of the enzyme-substrate complex is dictated by the induced-fit mechanism.^[1]

The main function of glucanase is to catalyze the hydrolysis of glycosidic bonds in polysaccharides. This function is not highly specific, and the enzymes distinguish among substrates mostly by the types of bonds present and α- or β- configuration.^[3]

In 1953, Dr. D. E. Koshland proposed a double-displacement mechanism for this enzyme action.^[4] The first step of his proposed mechanism is rate-limiting step independent of the concentration of the substrate and involves an amino acid nucleophile and an acid/base catalyst.^[4] In this step, the nucleophile, with help from the acid residue, displaces the aglycone and forms a covalent glycosyl-enzyme intermediate.^[4][1] The second step involves a water molecule, assisted by the conjugate base of the acid catalyst, rendering the free sugar while retaining an anomeric configuration of the molecule.^[1]

Glucanases can also catalyze transglycosylation, resulting in new β-glycosidic bonds between donor and acceptor saccharides.^[1] This reaction, which has the same region- and stereo-specificity as the hydrolysis reaction, involves either the direct reversal of hydrolysis (known as condensation) or kinetic control of a glycosyl donor substrate.^[1]

Bacteria such as Escherichia coli, and Bacillus spp. produce 1,3-1,4-β-glucanases in order to degrade and use polysaccharides from their environment as an energy source.^[1] These bacterial glucanases are an example of convergent evolution as they share similarity or relation with plant glucanase primary, secondary, or tertiary structure.^[1] Glucanases have also been found to be secreted by fungi such as Trichoderma harzianum, Saccharomyces cerevisiae and the anaerobic fungi Orpinomyces and Neocallimastigomycota, found in the digestive tracts of herbivores.^[1][5][6] T. harzianum is also used as a fungicide, which is linked to the ability of its β-gluanases to hydrolyze phytopathogenic fungi via a mycoparasitic attack.^[6]

Barley 1,3-1,4-β-glucanases are heat inactivated during malting, which can cause the build-up of high molecular-weight glucans which in turn result in reduced extract yield, lower filtration rates, and even gelatinous precipitates in the finished product. As a remedy, heat-resistant bacterial 1,3-1,4-β-glucanases are added.^[1]

Used in enological practices during the aging process of wine, particularly when aged on lees with microxygenation. The enzyme aids in autolysis of yeast cells to release polysaccharides and mannoproteins, which is believed to aid in the color and texture of the wine.

In the production of feedstuff for broiler chickens and piglets, it has been found that β-glucanases improve digestibility of barley-based diets.^[1]

• Glycoside hydrolases, a family of enzyme that cut a glycoside from a non-glycosidic molecule
• Glycoside hydrolase family 5
• Glycoside hydrolase family 16
• Glycoside hydrolase family 17