2021
DOI: 10.1007/978-1-0716-1826-4_10
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Using Molecular Simulation to Guide Protein Engineering for Biocatalysis in Organic Solvents

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Cited by 8 publications
(7 citation statements)
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“…Integrating the experimental results of enzymatic activity profiles and the comprehensive computational studies, we found the reduced specific activity of all three enzymes (BSLA, CBHI, and EG) mainly resulted from three factors: (i) increased structural compactness, (ii) overall water stripping, and (iii) competitive inhibition by glycerol in the substrate binding site. Previous studies also confirmed such factors played essential roles in modifying the solvent resistance and enzyme activity in nonconventional media. ,, …”
Section: Resultsmentioning
confidence: 59%
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“…Integrating the experimental results of enzymatic activity profiles and the comprehensive computational studies, we found the reduced specific activity of all three enzymes (BSLA, CBHI, and EG) mainly resulted from three factors: (i) increased structural compactness, (ii) overall water stripping, and (iii) competitive inhibition by glycerol in the substrate binding site. Previous studies also confirmed such factors played essential roles in modifying the solvent resistance and enzyme activity in nonconventional media. ,, …”
Section: Resultsmentioning
confidence: 59%
“…Previous studies also confirmed such factors played essential roles in modifying the solvent resistance and enzyme activity in nonconventional media. 43,58,77 As shown in Figure 1, the phenomena of decrease (i.e., BSLA), activation (i.e., CBHI), and neutralization (i.e., EG) were all detected by the experimental stability performance studies as incubation time changes. Our MD simulation studies also demonstrated that learning the role of glycerol in modifying the stability of enzymes is a pretty complicated task.…”
Section: The Overall Structural Change Of Enzymes In Various Concentr...mentioning
confidence: 90%
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“…Enhancing enzyme thermal stability employs varied methods such as media engineering, chemical modification, protein engineering, and immobilization . Protein engineering, especially computer-aided rational design, garners attention .…”
Section: Introductionmentioning
confidence: 99%
“…subtilis Lipase A (also known as Lipase A and LipA) is one of the smallest known lipases, consisting of just 181 amino acid residues . LipA, with an α–β hydrolase fold (Figure A), has been a subject of many experimental and computational studies with an aim to enhance its thermostability, catalytic activity, and solvent resistance. The catalytic triad consists of Ser77, Asp133, and His156. It is characterized as a lidless lipase because of the lack of interfacial activation (for the triacetyl glycerol substrate) and the absence of any conventional lid structure (usually a loop or α-helix covering the active site) in the crystal structures (CS). , However, exchanging the loop Ala39-Gly52 with an existing lid sequence has been reported to reduce the catalytic activity of LipA in an aqueous solution, which raised the question if this particular loop can be considered as a lid for LipA .…”
Section: Introductionmentioning
confidence: 99%