Your search keyword '"Miguel Alcalde"' showing total 4 results

1. Corrigendum: Mapping Potential Determinants of Peroxidative Activity in an Evolved Fungal Peroxygenase From Agrocybe aegerita

Author

Patricia Molina-Espeja, Alejandro Beltran-Nogal, Maria Alejandra Alfuzzi, Victor Guallar, and Miguel Alcalde

Subjects

fungal unspecific peroxygenase, peroxidative activity, peroxygenative activity, long range electron transfer pathway, heme access channel, directed evolution, Biotechnology, TP248.13-248.65

Published

2021

2. Mapping Potential Determinants of Peroxidative Activity in an Evolved Fungal Peroxygenase from Agrocybe aegerita

Author

Patricia Molina-Espeja, Alejandro Beltran-Nogal, Maria Alejandra Alfuzzi, Victor Guallar, and Miguel Alcalde

Subjects

Fungal unspecific peroxygenase, peroxidative activity, peroxygenative activity, long range electron transfer pathway, heme access channel, directed evolution, Biotechnology, TP248.13-248.65

Abstract

Fungal unspecific peroxygenases (UPOs) are hybrid biocatalysts with peroxygenative activity that insert oxygen into non-activated compounds, while also possessing convergent peroxidative activity for one electron oxidation reactions. In several ligninolytic peroxidases, the site of peroxidative activity is associated with an oxidizable aromatic residue at the protein surface that connects to the buried heme domain through a long-range electron transfer (LRET) pathway. However, the peroxidative activity of these enzymes may also be initiated at the heme access channel. In this study, we examined the origin of the peroxidative activity of UPOs using an evolved secretion variant (PaDa-I mutant) from Agrocybe aegerita as our point of departure. After analyzing potential radical-forming aromatic residues at the PaDa-I surface by QM/MM, independent saturation mutagenesis libraries of Trp24, Tyr47, Tyr79, Tyr151, Tyr265, Tyr281, Tyr293 and Tyr325 were constructed and screened with both peroxidative and peroxygenative substrates. These mutant libraries were mostly inactive, with only a few functional clones detected, none of these showing marked differences in the peroxygenative and peroxidative activities. By contrast, when the flexible Gly314-Gly318 loop that is found at the outer entrance to the heme channel was subjected to combinatorial saturation mutagenesis and computational analysis, mutants with improved kinetics and a shift in the pH activity profile for peroxidative substrates were found, while they retained their kinetic values for peroxygenative substrates. This striking change was accompanied by a 4.5°C enhancement in kinetic thermostability despite the variants carried up to four consecutive mutations. Taken together, our study proves that the origin of the peroxidative activity in UPOs, unlike other ligninolytic peroxidases described to date, is not dependent on a LRET route from oxidizable residues at the protein surface, but rather it seems to be exclusively located at the heme access channel.

Published

2021

3. Consensus Design of an Evolved High-Redox Potential Laccase

Author

Bernardo J. Gomez-Fernandez, Valeria A. Risso, Jose M. Sanchez-Ruiz, and Miguel Alcalde

Subjects

consensus design, high-redox potential laccase, ancestor mutation, thermostability, activity, Biotechnology, TP248.13-248.65

Abstract

Among the broad repertory of protein engineering methods that set out to improve stability, consensus design has proved to be a powerful strategy to stabilize enzymes without compromising their catalytic activity. Here, we have applied an in-house consensus method to stabilize a laboratory evolved high-redox potential laccase. Multiple sequence alignments were carried out and computationally refined by applying relative entropy and mutual information thresholds. Through this approach, an ensemble of 20 consensus mutations were identified, 18 of which were consensus/ancestral mutations. The set of consensus variants was produced in Saccharomyces cerevisiae and analyzed individually, while site directed recombination of the best mutations did not produce positive epistasis. The best single variant carried the consensus-ancestral A240G mutation in the neighborhood of the T2/T3 copper cluster, which dramatically improved thermostability, kinetic parameters and secretion.

Published

2020

4. Consensus Design of an Evolved High-Redox Potential Laccase

Author

Jose M. Sanchez-Ruiz, Valeria A. Risso, Bernardo J. Gómez-Fernández, and Miguel Alcalde

Subjects

0301 basic medicine, Histology, Computer science, lcsh:Biotechnology, Saccharomyces cerevisiae, Stability (learning theory), Biomedical Engineering, Bioengineering, 02 engineering and technology, Computational biology, Consensus method, 03 medical and health sciences, consensus design, lcsh:TP248.13-248.65, ancestor mutation, Original Research, Thermostability, Laccase, biology, activity, Bioengineering and Biotechnology, Protein engineering, 021001 nanoscience & nanotechnology, biology.organism_classification, thermostability, Activity, High-redox potential laccase, high-redox potential laccase, 030104 developmental biology, Consensus design, Mutation (genetic algorithm), Epistasis, Ancestor mutation, 0210 nano-technology, Biotechnology

Abstract

Among the broad repertory of protein engineering methods that set out to improve stability, consensus design has proved to be a powerful strategy to stabilize enzymes without compromising their catalytic activity. Here, we have applied an in-house consensus method to stabilize a laboratory evolved high-redox potential laccase. Multiple sequence alignments were carried out and computationally refined by applying relative entropy and mutual information thresholds. Through this approach, an ensemble of 20 consensus mutations were identified, 18 of which were consensus/ancestral mutations. The set of consensus variants was produced in Saccharomyces cerevisiae and analyzed individually, while site directed recombination of the best mutations did not produce positive epistasis. The best single variant carried the consensus-ancestral A240G mutation in the neighborhood of the T2/T3 copper cluster, which dramatically improved thermostability, kinetic parameters and secretion., This study is based upon work funded by and the Spanish Government projects BIO2013-43407-R-DEWRY and BIO2016- 79106-R-Lignolution. BG-F was supported by a FPI national fellowship BES-2014-068887.

Published

2020