Amylase
Shane Riley
IntroductionIntroduction
Amylase is the first enzyme to be discovered. It was discovered and isolated by Anselme Payen in 1833. Amylases are hydrolases acting on on α-1,4-glycosidic bonds. Amylases can be further subdivided into α,β and γ amylases. α-Amylase is an enzyme that acts as a catalyst for the hydrolysis of alpha-linked polysaccharides into α-anomeric products. [1]The enzyme comes from a variety of sources, each with different characteristics. α-Amylase is found within in the human body as the enzyme active in pancreatic juice and salvia.
StructureStructure
BSTA comprises of a single polypeptide chain. This chain is folded into three domains A, B and C. These domains are generally recognized on α-amylase enzymes. The A domain constitutes the core structure, with a (β/α)barrel.The B domain consists of a sheet of four anti-parallel β-strands with a pair of anti-parallel β-strands. Long loops are observed between the β-strands. Located within the B domain is the binding site for Ca2+- Na+- Ca2+.Domain C consisting of eight β-strands assembles into a globular unit forming a Greek key motif. It also holds the third Ca2+ binding site in association with domain A.Positioned on the C-terminal side of the β-strands of the (β/ α)8barrel in domain A, is the active site. The catalytic residues involved in the active site are Asp234, Glu264, and Asp331, for BSTA. The residues are identical to other α-amylases, yet there are positional differences which reflect the flexible nature of catalytic resides. CaI, and CaII found at the interface of domain A and C, and CaIII with Na found in the interior of domain B, constitute the metal ion binding sites. CaI is consistent in all α-amylases, however there are differences between the linear trio of CaII, CaIII and Na in other enzymes.CaIII acts as a bridge between two loops, one from Aα6 of domain A, and between Cβ1 and Cβ2 of domain C.
FunctionFunction
In the human body α-amylase is part of digestion with the breakdown of carbohydrates in the diet. Salivary α-Amylase found in saliva, hydrolyzes the (α1-4) glycosidic linkages of starch seperating into polysaccharide fragments. Once the enzyme reaches the stomach it becomes inactivated due to the acidic pH.
Industrial UsesIndustrial Uses
Alpha amylase is used extensively in many various industrial processes. In textile weaving, starch is added for warping. After weaving, the starch is then later removed by through Bacillus subtilis α-amylase. Dextrin, a viscosity improver, filler or ingredient of food is manufactured by the liquefaction of starch by bacteria α-amylase. Bacterial α-amylases of B.subtilis, or B.licheniformis is used for the initial starch liquefaction in producing high conversion glucose syrup. texttext [2]
ReferencesReferences
- ↑ Suvd D, Fujimoto Z, Takase K, Matsumura M, Mizuno H. Crystal structure of Bacillus stearothermophilus alpha-amylase: possible factors determining the thermostability. J Biochem. 2001 Mar;129(3):461-8. PMID:11226887
- ↑ Suvd D, Fujimoto Z, Takase K, Matsumura M, Mizuno H. Crystal structure of Bacillus stearothermophilus alpha-amylase: possible factors determining the thermostability. J Biochem. 2001 Mar;129(3):461-8. PMID:11226887
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