Alpha-amylase catalytic domain | |||||||||
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cyclodextrin glucanotransferase (e.c.2.4.1.19) (cgtase) | |||||||||
Identifiers | |||||||||
Symbol | Alpha-amylase | ||||||||
Pfam | PF00128 | ||||||||
Pfam clan | CL0058 | ||||||||
InterPro | IPR006047 | ||||||||
SCOP | 1ppi | ||||||||
CAZy | GH13 | ||||||||
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Alpha-amylase C-terminal beta-sheet domain | |||||||||
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crystal structure of barley alpha-amylase isozyme 1 (amy1) inactive mutant d180a in complex with maltoheptaose | |||||||||
Identifiers | |||||||||
Symbol | Alpha-amyl_C2 | ||||||||
Pfam | PF07821 | ||||||||
InterPro | IPR012850 | ||||||||
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Alpha amylase, C-terminal all-beta domain | |||||||||
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maltotriose complex of preconditioned cyclodextrin glycosyltransferase mutant | |||||||||
Identifiers | |||||||||
Symbol | Alpha-amylase_C | ||||||||
Pfam | PF02806 | ||||||||
Pfam clan | CL0369 | ||||||||
InterPro | IPR006048 | ||||||||
SCOP | 1ppi | ||||||||
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α-Amylase is an enzyme that hydrolyses alpha-bonds of large alpha-linked polysaccharides such as starch and glycogen, yielding glucose and maltose.[1] It is the major form of amylase found in humans and other mammals.[2] It is also present in seeds containing starch as a food reserve, and is secreted by many fungi.
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Although found in many tissues, amylase is most prominent in pancreatic juice and saliva, each of which having its own isoform of human α-amylase. They behave differently on isoelectric focusing, and can also be separated in testing by using specific monoclonal antibodies. In humans, all amylase isoforms link to chromosome 1p21 (see AMY1A).
Amylase is found in saliva and breaks starch down into maltose and dextrin. This form of amylase is also called "ptyalin" /ˈtaɪəlɪn/.[3] It will break large, insoluble starch molecules into soluble starches (amylodextrin, erythrodextrin, achrodextrin), producing successively smaller starches and ultimately maltose. Ptyalin acts on linear α(1,4) glycosidic linkages, but compound hydrolysis requires an enzyme that acts on branched products. Salivary amylase is inactivated in the stomach by gastric acid. In gastric juice adjusted to pH 3.3, ptyalin was totally inactivated in 20 minutes at 37°C. In contrast, 50% of amylase activity remained after 150 minutes of exposure to gastric juice at pH 4.3.[4] Both starch, the substrate for ptyalin, and the product (short chains of glucose) are able to partially protect it against inactivation by gastric acid. Ptyalin added to buffer at pH 3.0 underwent complete inactivation in 120 minutes; however, addition of starch at a 0.1% level resulted in 10% of the activity remaining, and similar addition of starch to a 1.0% level resulted in about 40% of the activity remaining at 120 minutes.[5]
The salivary amylase gene has undergone duplication during evolution, and DNA hybridization studies indicate that many individuals have multiple tandem repeats of the gene. The number of gene copies correlates with the levels of salivary amylase, as measured by protein blot assays using antibodies to human amylase. Gene copy number is associated with apparent evolutionary exposure to high-starch diets.[6] For example, a Japanese individual had 14 copies of the amylase gene (one allele with 10 copies, and a second allele with 4 copies). The Japanese diet has traditionally contained large amounts of rice starch. In contrast, a Biaka individual carried six copies (three copies on each allele). The Biaka are rainforest hunter-gatherers who have traditionally consumed a low-starch diet. Perry and colleagues speculated that increased copy number of the salivary amylase gene may have enhanced survival coincident to a shift to a starchy diet during human evolution.
Pancreatic α-amylase randomly cleaves the α(1-4) glycosidic linkages of amylose to yield dextrin, maltose, or maltotriose. It adopts a double displacement mechanism with retention of anomeric configuration.
The test for amylase is easier to perform than that for lipase, making it the primary test used to detect and monitor pancreatitis. Labs will usually measure either pancreatic amylase or total amylase. If only pancreatic amylase is measured, an increase will not be noted with mumps or other salivary gland trauma.
However, because of the small amount present, timing is critical when sampling blood for this measurement. Blood should be taken soon after a bout of pancreatitis pain, otherwise it is excreted rapidly by the kidneys.
Salivary alpha-amylase has been used as a biomarker for stress that does not require a blood draw.[7]
Increased plasma levels in humans are found in:
Total amylase readings of over 10X the upper limit of normal (ULN) are suggestive of pancreatitis. Five to ten times the ULN may indicate ileus or duodenal disease or renal failure, and lower elevations are commonly found in salivary gland disease.
Alpha-amylase activity in grain is measured by, for instance, the Hagberg-Perten Falling Number, a test to assess sprout damages.[8], or the Phadebas method.
Alpha-amylase is used in ethanol production to break starches in grains into fermentable sugars.
The first step in the production of high-fructose corn syrup is the treatment of cornstarch with alpha-amylase, producing shorter chains of sugars called oligosaccharides.
An alpha-amylase called "Termamyl", sourced from Bacillus licheniformis, is also used in some detergents, especially dishwashing and de-starching detergents.[9]
It is reported that tris molecule inhibits a number of bacterial alpha-amylases,[10][11] and, therefore, they should not be used in tris buffer.
Several methods are available for determination of alpha-amylase activity, and different industries tend to rely on different methods. The starch iodine test, a development of the Iodine test, is based on colour change, as alpha amylase degrades starch and is commonly used in many applications. A similar but industrially produced test is the Phadebas Amylase Test, which is used as a qualitative and quantitative test within many industries such as detergents, various food, grain, malt, and forensic biology.
Alpha-amylases contain a number of distinct protein domains. The catalytic domain has a structure consisting of an 8-stranded alpha/beta barrel that contains the active site, interrupted by a ~70-amino acid calcium-binding domain protruding between beta strand 3 and alpha helix 3, and a carboxyl-terminal Greek key beta-barrel domain.[12] Several alpha-amylases contain a beta-sheet domain, usually at the C terminus. This domain is organised as a five-stranded anti-parallel beta-sheet.[13][14] Several alpha-amylases contain an all-beta domain, usually at the C terminus.[15]
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This article incorporates text from the public domain Pfam and InterPro IPR006047 This article incorporates text from the public domain Pfam and InterPro IPR012850 This article incorporates text from the public domain Pfam and InterPro IPR006048