2013
DOI: 10.1016/j.jbiosc.2013.04.018
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Site-directed mutagenesis of methionine residues for improving the oxidative stability of α-amylase from Thermotoga maritima

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Cited by 18 publications
(6 citation statements)
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“…Related crystallographic studies have shown that when a substrate (or inhibitor) binds to the active site of αmannosidase, the mannose ring is converted from a stable chair conformation to an unstable boat conformation [32,47], which is required for catalysis and strong interaction with the Zn 2+ cofactor at the active site [24]. The β-mannanases (EC3.2.1.78) mutant screened by Zhang et al by random mutation showed a significant improvement in specific activity and thermal stability compared with the parental one [44]; Ozturk et al found that a-amylase's oxidative stability was significantly increased by changing four methionine-containing sites (43, 44, 55, and 62) on that enzyme to alanine [25]. These reseach further indicate that a slight conformational change appears to influence the substrate-binding and enzyme catalytic characteristics [14].…”
Section: Discussion:mentioning
confidence: 99%
“…Related crystallographic studies have shown that when a substrate (or inhibitor) binds to the active site of αmannosidase, the mannose ring is converted from a stable chair conformation to an unstable boat conformation [32,47], which is required for catalysis and strong interaction with the Zn 2+ cofactor at the active site [24]. The β-mannanases (EC3.2.1.78) mutant screened by Zhang et al by random mutation showed a significant improvement in specific activity and thermal stability compared with the parental one [44]; Ozturk et al found that a-amylase's oxidative stability was significantly increased by changing four methionine-containing sites (43, 44, 55, and 62) on that enzyme to alanine [25]. These reseach further indicate that a slight conformational change appears to influence the substrate-binding and enzyme catalytic characteristics [14].…”
Section: Discussion:mentioning
confidence: 99%
“…Therefore, we can speculate that the participation of the SW molecule leads to the conformational change of the mannose ring, and the hydroxyl group at the 1 and 2 positions of the SW molecule plays an important role, preventing the hydrolysis of mannosidase. Compared with the parent, the β-mannanases (EC3.2.1.78) mutant screened by Zhang et al through random mutation has greatly improved speci c activity and thermal stability [34]; Another example is the mutation of four sites (43,44,55, and 62) with methionine on -amylase to alanine, the oxidative stability of the enzyme was signi cantly improved [35]. This further indicated that a slight conformational change appears to in uence the substrate-binding and enzyme catalytic characteristics [36].…”
Section: Discussionmentioning
confidence: 99%
“…However, this study ( Ozturk et al, 2013 ) had proven that the mutation at near-to-active-site methionine residue (M55A) was more significant than mutation of solvent-accessible methionine residues (M43A + M44A) in terms of oxidative stability, where both types of methionine residues were proven to be oxidation prone ( Lin et al, 2003 ; Yang et al, 2012 ). This statement was justified when M55A mutant retained 50% of its initial activity in the presence of 100 mM H 2 O 2 , compared to double mutant (M43A + M44A) at 39% ( Ozturk et al, 2013 ). Nevertheless, such investigations and engineering to improve oxidative stability of microbial -amylases remain underexplored and should not become obsolete (latest report in 2013; Table 2 ) due to its great interests and advantages in detergent industry.…”
Section: Survey Methodologymentioning
confidence: 99%