Your search keyword '"Ferrer, Manuel"' showing total 2 results

1. Biochemical studies on a versatile esterase that is most catalytically active with polyaromatic esters.

Author

Martínez-Martínez M, Lores I, Peña-García C, Bargiela R, Reyes-Duarte D, Guazzaroni ME, Peláez AI, Sánchez J, and Ferrer M

Subjects

Bacteria enzymology, Bacteria genetics, Cluster Analysis, Enzyme Stability, Esterases chemistry, Esterases genetics, Esterases isolation & purification, Hydrogen-Ion Concentration, Phylogeny, Sequence Homology, Substrate Specificity, Temperature, Esterases metabolism, Hydrocarbons, Aromatic metabolism, Polyesters metabolism

Abstract

Herein, we applied a community genomic approach using a naphthalene-enriched community (CN1) to isolate a versatile esterase (CN1E1) from the α/β-hydrolase family. The protein shares low-to-medium identity (≤ 57%) with known esterase/lipase-like proteins. The enzyme is most active at 25-30°C and pH 8.5; it retains approximately 55% of its activity at 4°C and less than 8% at ≥ 55°C, which indicates that it is a cold-adapted enzyme. CN1E1 has a distinct substrate preference compared with other α/β-hydrolases because it is catalytically most active for hydrolysing polyaromatic hydrocarbon (phenanthrene, anthracene, naphthalene, benzoyl, protocatechuate and phthalate) esters (7200-21 000 units g(-1) protein at 40°C and pH 8.0). The enzyme also accepts 44 structurally different common esters with different levels of enantio-selectivity (1.0-55 000 units g(-1) protein), including (±)-menthyl-acetate, (±)-neomenthyl acetate, (±)-pantolactone, (±)-methyl-mandelate, (±)-methyl-lactate and (±)-glycidyl 4-nitrobenzoate (in that order). The results provide the first biochemical evidence suggesting that such broad-spectrum esterases may be an ecological advantage for bacteria that mineralize recalcitrant pollutants (including oil refinery products, plasticizers and pesticides) as carbon sources under pollution pressure. They also offer a new tool for the stereo-assembly (i.e. through ester bonds) of multi-aromatic molecules with benzene rings that are useful for biology, chemistry and materials sciences for cases in which enzyme methods are not yet available., (© 2014 The Authors. Microbial Biotechnology published by John Wiley & Sons Ltd and Society for Applied Microbiology.)

Published

2014

2. Inter-conversion of catalytic abilities in a bifunctional carboxyl/feruloyl-esterase from earthworm gut metagenome.

Author

Vieites, José Marúa, Ghazi, Azam, Beloqui, Ana, Polaina, Julio, Andreu, José M., Golyshina, Olga V., Nechitaylo, Taras Y., Waliczek, Agnes, Yakimov, Michail M., Golyshin, Peter N., and Ferrer, Manuel

Subjects

CATALYSIS, GENE conversion, CARBOXYLIC acids, ESTERASES, EARTHWORMS, GENOMES

Abstract

Carboxyl esterases (CE) exhibit various reaction specificities despite of their overall structural similarity. In present study we have exploited functional metagenomics, saturation mutagenesis and experimental protein evolution to explore residues that have a significant role in substrate discrimination. We used an enzyme, designated 3A6, derived from the earthworm gut metagenome that exhibits CE and feruloyl esterase (FAE) activities with p-nitrophenyl and cinnamate esters, respectively, with a [( kcat/ Km)]CE/[( kcat/ Km)]FAE factor of 17. Modelling-guided saturation mutagenesis at specific hotspots (Lys281, Asp282, Asn316 and Lys317) situated close to the catalytic core (Ser143/Asp273/His305) and a deletion of a 34-AA–long peptide fragment yielded mutants with the highest CE activity, while cinnamate ester bond hydrolysis was effectively abolished. Although, single to triple mutants with both improved activities (up to 180-fold in kcat/ Km values) and enzymes with inverted specificity (( kcat/ Km)CE/( kcat/ Km)FAE ratio of ∼0.4) were identified, no CE inactive variant was found. Screening of a large error-prone PCR-generated library yielded by far less mutants for substrate discrimination. We also found that no significant changes in CE activation energy occurs after any mutation (7.3 to −5.6 J mol−1), whereas a direct correlation between loss/gain of FAE function and activation energies (from 33.05 to −13.7 J mol−1) was found. Results suggest that the FAE activity in 3A6 may have evolved via introduction of a limited number of ‘hot spot’ mutations in a common CE ancestor, which may retain the original hydrolytic activity due to lower restrictive energy barriers but conveys a dynamic energetically favourable switch of a second hydrolytic reaction. [ABSTRACT FROM AUTHOR]

Published

2010