Amylase: Difference between revisions
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< | <StructureSection load='' size='350' side='right' scene='Sandbox_182/Alpha-amylase/1' caption='Amylase complex with Ca+2 (green) and Na+ (purple) ions (PDB code [[1hvx]])'> | ||
=Introduction= | |||
Discovered and isolated by [http://en.wikipedia.org/wiki/Anselme_Payen Anselme Payen] in 1833, '''amylase''' was the first enzyme to be discovered<ref name="book">Yamamoto T.1988. Handbook of Amylases and Related Enzymes: Their Sources, Isolation Methods, Properties and Applications. Osaka Japan: Pergamon Press</ref>. Amylases are hydrolases, acting on α-1,4-glycosidic bonds<ref name="Path">PMID:9541387</ref>. They can be further subdivided into α,β and γ amylases<ref name="book"/>.'''α-Amylase''' (AAM) is an enzyme that acts as a catalyst for the hydrolysis of α-linked polysaccharides into α-anomeric products<ref name="Main">PMID:11226887</ref>. The enzyme can be derived from a variety of sources, each with different characteristics. α-Amylase found within the human body serves as the enzyme active in pancreatic juice and saliva<ref name="Path"/>. α-Amylase is not only essential in human physiology but has a number of important biotechnological functions in various processing industries. '''β/α amylase''' (BAAM) is a precursor protein which is cleaved to form the β-amylase and α-amylase after secretion. '''β amylase''' (BAM) acts at the non-reducing chain ends and liberate only β-maltose<ref>PMID:6168260</ref>. '''γ amylase''' (GAM) acts at the non-reducing chain ends of amylose and amylopectin and liberates glucose. '''Pullulanase''' hydrolyses the α-1,6 glucoside linkage in starch, amylopectin, pullulan and related oligosaccharides<ref>PMID:22991654</ref>.<br /> | |||
*'''Neopullulanase''' is involved in starch degrading<ref>PMID:8955399</ref>.<br /> | |||
For α-amylase see [[Raghad zoubi]]<br /> | |||
See also [[Amylase (Hebrew)]]. | |||
=Structure<ref name="Main"/>= | |||
== | Shown as 1hvx is the structure of the thermostable α-amylase of ''Bacillus stearothermophilus'' (BSTA)<ref name="Main"/>. BSTA is comprised of a single polypeptide chain. This chain is folded into three domains: A, B and C. These domains are generally found on all α-amylase enzymes. The <scene name='Sandbox_182/Domain_aa/1'>A domain </scene>constitutes the core structure, with a (β/α)<sub>8</sub>-barrel.The <scene name='Sandbox_182/Domain_a/1'> B domain</scene> 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 <scene name='Sandbox_182/Trio/1'>binding site</scene> for Ca<sup>2+</sup>-Na<sup>+</sup>-Ca<sup>2+</sup>. <scene name='Sandbox_182/Domain_c/1'>Domain C </scene>consisting of eight β-strands is assembled into a globular unit forming a Greek key motif. It also holds the <scene name='Sandbox_182/Caiii/1'>third </scene>Ca<sup>2+</sup> binding site in association with domain A. Positioned on the C-terminal side of the β-strands of the (β/α)<sub>8</sub>-barrel in domain A is the active site. The catalytic residues involved for the BSTA active site are <scene name='38/382954/Active_site_ball_stick/2'>Asp234, Glu264, and Asp331</scene>. The residues are identical to other α-amylases, yet there are positional differences which reflect the flexible nature of catalytic resides. | ||
<scene name='Sandbox_182/Trio/1'>CaII and CaI with Na</scene> found in the interior of domain B and <scene name='Sandbox_182/Caiii/2'>CaIII </scene>at the interface of domain A and C, constitute the metal ion binding sites. All α-amylases contain one strongly conserved Ca<sup>2+</sup> ion for structural integrity and enzymatic activity.<ref name="chloride">PMID: 12021442</ref> CaI is consistent in α-amylases, however there are structural differences between the linear trio of CaI, CaII and Na in other enzymes. CaIII acts as a bridge between two loops, one from α6 of domain A, and one between β1 and β2 of domain C. | |||
==Chloride Dependent Enzymes== | |||
A family of chloride-dependent enzymes, including salivary and pancreatic α-amylase, require the binding of a chloride ion to be allosterically activated<ref name="chloride"/>. The function of the chloride ion still remains uncertain. No relationship has been observed between the anion binding affinity and its activity, indicating the complexity between the binding parameters and mechanism it activates<ref name="chloride"/>. Studies have shown that nitrite and nitrate ions with pancreatic α-amylase fit within the chloride binding site, thus making all the necessary hydrogen bonds and enhancing the relative activity by 5-fold<ref>PMID: 18284212</ref>. | |||
== | =Function= | ||
==Mechanism== | |||
In the human body, α-amylase is part of digestion with the breakdown of carbohydrates in the diet. The mechanism involved includes catalyzing substrate hydrolysis by a double replacement mechanism, forming a covalent glycosyl-enzyme intermediate and hydrolyzed through oxocarbenium ion-like transition states<ref name="human"/>. One of the carboxylic acids in the active site acts as the catalytic nucleophile during the formation of the intermediate. A second carboxylic acid operates as the acid/base catalyst, supporting the stabilization of the transition states during the hydrolysis<ref name="human">PMID: 18284212</ref>. | |||
== | |||
In the human body α-amylase is part of digestion with the breakdown of carbohydrates in the diet. | |||
==Human Salivary and Pancreatic α-Amylase== | |||
Salivary α-Amylase hydrolyzes the (α1-4) glycosidic linkages of starch, separating it into short polysaccharide fragments<ref name="Japan"> PMID: 16232518</ref>. Once the enzyme reaches the stomach, it becomes inactivated due to the acidic pH. Further breakdown of starch occurs by secretion of a second form of the enzyme by the pancreas. Pancreatic juice enters the duodenum and pancreatic α-amylase further cleaves starch to yield maltose, maltotriose and oligosaccharides<ref name="Japan"/>. The oligosaccharides are referred to as dextrins, which are fragments of amylopectin consisting of (α1-6)branch points<ref name="Japan"/>. Microvilli of the intestinal epithelia break maltose and dextrins into glucose, which gets absorbed into the circulatory system<ref name="Japan"/>. Glycogen has a relatively similar structure as starch, and thus proceeds in the same digestive pathway. | |||
= | |||
==Regulation== | |||
α-Amylase is regulated through a number of inhibitors. These inhibitors are classified according to six categories, based on their tertiary structures<ref name="inhibit">PPMID: 17713601</ref>. Inhibitors of α-amylase block the active site of the enzyme. In animals, inhibitors control the conversion of starch to simple sugars during glucose peaks after a meal so that breakdown of glucose occurs at a rate the body can handle<ref name="inhibit"/>. This is particularly important for diabetics, who require low quantities of α-amylase to maintain control over glucose levels. After taking insulin however, pancreatic α-amylase escalates. Plants use these inhibitors as a defense mechanism to inhibit the use of α-amylase in insects, thus protecting themselves from herbivory<ref>PMID: 11856298 </ref>. | |||
=Industrial Uses= | |||
α-Amylase is used extensively in various industrial processes. In textile weaving, starch is added for warping. After weaving, the starch is removed by ''Bacillus subtilis'' α-amylase<ref name="book"/>. Dextrin, which is a viscosity improver, filler, or ingredient of food, is manufactured by the liquefaction of starch by bacteria α-amylase<ref name="book"/>. Bacterial α-amylases of ''B.subtilis'', or ''B.licheniformis'' are used for the initial starch liquefaction in producing high conversion glucose syrup<ref name="book"/>. Pancreatitis can be tested by determining the level of amylases in the blood, a result of damaged amylase-producing cells, or excretion due to renal failure<ref>PMID: 16286272 </ref>. α-Amylase is used for the production of malt, as the enzyme is produced during the germination of cereal grains<ref name="book"/>. | |||
β/α amylase (BAAM) is a precursor protein which is cleaved to form the β-amylase and α-amylase after secretion. | |||
= Structure of the AmyC GH13 alpha-amylase from Alicyclobacillus sp, reveals accommodation of starch branching points in the alpha-amylase family<ref>doi 10.1107/S2059798318014900</ref> = | |||
The enzymatic degradation of starch has a myriad industrial applications. However, the branched nature of the polysaccharides that compose it poses problems, as branches have to be accommodated within an active centre best suited to linear polysaccharides. Alpha-amylases are glycoside hydrolases that break the α-1,4 bonds in starch and related glycans. The present work provides a rare insight into branch-point acceptance in these industrial catalysts. | |||
The complex of α-amylase from ''Alicyclobacillus sp.'' 18711 (AliC) with acarbose was solved by molecular replacement, with two molecules of AliC in the asymmetric unit, at a resolution of 2.1 Å ([[6gxv]]). The fold, as expected, is a canonical <scene name='79/799580/Cv1/5'>three-domain arrangement</scene> with the A, B and C domains defined approximately as <span style="color:deepskyblue;background-color:black;font-weight:bold;">A, residues 4–104 and 210–397 (in deepskyblue)</span>, <span style="color:yellow;background-color:black;font-weight:bold;">B, residues 105–209 (in yellow)</span>, and <span style="color:white;background-color:black;font-weight:bold;">C, residues 398–484 (in white)</span>. A classical Ca<sup>2+</sup>–Na<sup>+</sup>–Ca<sup>2+</sup> <scene name='79/799580/Cv1/4'>triad</scene> <ref name="Machius">PMID:9551551</ref>,<ref name="Brzozowski">PMID:10924103</ref> is found at the A/B-domain interface. The structure of AliC was determined in the presence of the <scene name='79/799580/Cv1/6'>inhibitor acarbose</scene> (<span style="color:lime;background-color:black;font-weight:bold;">colored in green</span>). As with many (retaining) α-amylase complexes, the acarbose is observed as a transglycosylated species, here a hexasaccharide which contains two of the acarviosin disaccharide motifs. The <scene name='79/799580/Cv/11'>complex defines six subsites</scene>, -4 to +2, with the expected catalytic GH13 signature triad of Asp234 (nucleophile), Glu265 (acid/base) and <scene name='79/799580/Cv/13'>Asp332 (interacting with O2/O3 of the -1 subsite sugar)</scene> all disposed for catalysis, here around the <sup>2</sup>H<sub>3</sub> half-chair of the unsaturated cyclohexitol moiety. AliC must also be able to accommodate branching in the +2 subsite, which is consistent with the <scene name='79/799580/Cv/14'>glucose moiety seen adjacent to O6 of the +2 sugar</scene>. | |||
*<scene name='79/799580/Cv/12'>Asp234 and Glu265 interactions</scene>. | |||
A ‘branched-ligand’ AliC complex was obtained through co-crystallization, with crystals forming in a new space group. This form diffracted poorly and data could only be obtained to 2.95 Å resolution [[6gya]]). Weak density in the -1 subsite, largely diffuse but greater than would be expected for discrete solvent, remained unmodelled. Density was clearer for a panose trisaccharide with an α-1,4-linked disaccharide in subsites +1 and +2 and, crucially, clear density for an α-1,6 branch accommodated in the +1 subsite, providing a structural context for the limit digest analysis of action on amylopectin starch. The <scene name='79/799580/Cv/15'>binding of the branched oligosaccharide in subsites +1, +2 and +1'</scene> (<span style="color:lime;background-color:black;font-weight:bold;">oligosaccharide colored in green</span>). | |||
=3D structures of amylase= | |||
[[Amylase 3D structures]] | |||
</StructureSection> | |||
=References= | =References= | ||
<references/> | <references/> | ||
[[Category:Topic Page]] | |||
[[he:Amylase (Hebrew)]] | |||