Molecular engineering of Rhizopus oryzae lipase using a combinatorial protein library constructed on the yeast cell surface

We constructed a combinatorial yeast library through cell-surface display of the pro- and mature region of lipase from Rhizopus oryzae (ProROL) and obtained clones retaining lipase activity in fluorescent plate assay. The initial reaction rates of hydrolysis and methanolysis could be measured directly as whole-cell biocatalyst without complex treatments such as concentration, purification, and immobilization. The selected clones showed wide-ranging variation of reaction specificity. The K138R mutant showed a 1.3-fold shift of reaction specificity toward methanolysis compared to the wild type, while the V-95D, I53V, P-96S/F196Y, and Q128H/Q197L mutants showed shifts toward hydrolysis of 1.6–5.9-fold. Predictions of the mutants’ three-dimensional structure suggested that the hydrogen-bond distance between threonine 83 and aspartic acid 92 may influence reaction specificity, which shifted toward hydrolysis in mutants where this distance was shorter than in the wild type, but toward methanolysis where it was longer. The positions of amino acid residues (aa) 53, 138 and 196 in ProROL are considered the sites that influence hydrogen-bond distance and change reaction specificity. Construction of a surface-displayed combinatorial library in yeast cells is thus a powerful tool in accelerating the combinatorial approach to enzyme engineering and novel whole-cell biocatalyst development.