Iterative saturation mutagenesis was performed over six residues delimiting the substrate binding pocket of a high-redox potential chimeric laccase with the aim of enhancing its activity over sinapic acid, a lignin-related phenol of industrial interest. In total, more than 15000 clones were screened and two selected variants, together with the parent-type laccase, were purified and characterized. The new variants presented shifted pH activity profiles and enhanced turnover rates on sinapic acid and its methyl ester, whereas the oxidation of related phenols was not significantly enhanced. Neither the enzyme's redox potential nor the mechanism of the reaction were affected. Thus, quantum mechanics and molecular dynamics calculations were done to rationalize the effect of the selected mutations, revealing the critical role of the residues of the enzyme pocket to provide the precise binding of the substrate that enables an efficient electron transfer to the T1 copper. The results presented highlight the power of combining directed evolution and computational approaches to give novel solutions in enzyme engineering and to understand the mechanistic reasons behind them, offering new insights for further rational design towards specific targets.
Re-designing the substrate binding pocket of laccase for enhanced oxidation of sinapic acid / Pardo, Isabel; Santiago, Gerard; Gentili, Patrizia; Lucas, Fatima; Monza, Emanuele; Medrano, Francisco Javier; Galli, Carlo; Ferrer, Angel Tomas Martinez; Guallar, Victor; Camarero, Susana. - In: CATALYSIS SCIENCE & TECHNOLOGY. - ISSN 2044-4753. - STAMPA. - 6:(2016), pp. 3900-3910. [10.1039/C5CY01725D]
Re-designing the substrate binding pocket of laccase for enhanced oxidation of sinapic acid
GENTILI, Patrizia;GALLI, Carlo;
2016
Abstract
Iterative saturation mutagenesis was performed over six residues delimiting the substrate binding pocket of a high-redox potential chimeric laccase with the aim of enhancing its activity over sinapic acid, a lignin-related phenol of industrial interest. In total, more than 15000 clones were screened and two selected variants, together with the parent-type laccase, were purified and characterized. The new variants presented shifted pH activity profiles and enhanced turnover rates on sinapic acid and its methyl ester, whereas the oxidation of related phenols was not significantly enhanced. Neither the enzyme's redox potential nor the mechanism of the reaction were affected. Thus, quantum mechanics and molecular dynamics calculations were done to rationalize the effect of the selected mutations, revealing the critical role of the residues of the enzyme pocket to provide the precise binding of the substrate that enables an efficient electron transfer to the T1 copper. The results presented highlight the power of combining directed evolution and computational approaches to give novel solutions in enzyme engineering and to understand the mechanistic reasons behind them, offering new insights for further rational design towards specific targets.| File | Dimensione | Formato | |
|---|---|---|---|
|
Pardo_Re-designing_2016_accepted.pdf
accesso aperto
Note: accepted manuscript
Tipologia:
Documento in Pre-print (manoscritto inviato all'editore, precedente alla peer review)
Licenza:
Tutti i diritti riservati (All rights reserved)
Dimensione
1.77 MB
Formato
Adobe PDF
|
1.77 MB | Adobe PDF | |
|
Pardo_Re-designing_2016.pdf
accesso aperto
Note: full text - editor PDF
Tipologia:
Versione editoriale (versione pubblicata con il layout dell'editore)
Licenza:
Creative commons
Dimensione
2.89 MB
Formato
Adobe PDF
|
2.89 MB | Adobe PDF |
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
