Novy_2021_J.Biol.Chem__101302

Cutinases are esterases that release fatty acids from the apoplastic layer in plants. As they accept bulky and hydrophobic substrates, cutinases could be used in many applications, ranging from valorization of bark-rich side streams to plastic recycling. Advancement of these applications with cutinases as biocatalysts, however, requires deeper knowledge of the enzymes' biodiversity and structure-function relationships. Here, we mined over 3000 members from Carbohydrate Esterase family 5 (CE5) for putative cutinases and condensed it to 151 genes from known or putative lignocellulose-targeting organisms. The 151 genes were subjected to a phylogenetic analysis. While cutinases with available crystal structures were phylogenetically closely related, we selected nine phylogenic diverse cutinases for characterization. The nine selected cutinases were recombinantly produced and their kinetic activity was characterized against para-nitrophenol substrates esterified with consecutively longer alkyl chains (pNP-C(2) to C(16)). The investigated cutinases each had a unique activity fingerprint against tested pNP-substrates. The five enzymes with the highest activity on pNP-C(12) and C(16), indicative of activity on bulky hydrophobic compounds, were selected for in-depth kinetic and structure-function analysis. All five enzymes showed a decrease in k(cat) values with increasing substrate chain length, while K(M) values and binding energies (calculated from in silico docking analysis) improved. Two cutinases from Fusarium solani and Cryptococcus sp. exhibited outstandingly low K(M) values, resulting in high catalytic efficiencies towards pNP-C(16). Docking analysis suggested that different clades of the phylogenetic tree may harbor enzymes with different modes of substrate interaction, involving a solvent-exposed catalytic triad, a lipase-like lid, or a clamshell-like active site possibly formed by flexible loops.