The activity of urate oxidase was lost during hominoid evolution, resulting in high susceptibility to hyperuricemia and gout in humans. In order to develop a more "human-like" uricase for therapeutic use, exon replacement/restoration and site-directed mutagenesis were performed to obtain porcine-human uricase with higher homology to deduced human uricase (dHU) and increased uricolytic activity. In an exon replacement study, substitution of exon 6 in wild porcine uricase (wPU) gene with corresponding exon in dhu totally abolished its activity. Substitutions of exon 5, 3, and 1-2 led to 85%, 60%, and 45% loss of activity, respectively. However, replacement of exon 4 and 7-8 did not significantly change the enzyme activity. When exon 5, 6, and 3 in dhu were replaced by their counterparts in wpu, the resulting chimera H1-2P₃H₄P5-6H7-8 was active, but only about 28% of wPU. Multiple sequence alignment and homology modeling predicted that mutations of E24D and E83G in H1-2P₃H₄P5-6H7-8 were favorable for further increase of its activity. After site-directed mutagenesis, H1-2P₃H₄P5-6H7-8 (E24D & E83G) with increased homology (91.45%) with dHU and higher activity and catalytic efficiency than the FDA-approved porcine-baboon chimera (PBC) was obtained. It showed optimum activity at pH 8.5 and 35 °C and was stable in a pH range of 6.5-11.0 and temperature range of 20-40 °C.
Keywords: exon replacement/restoration; site-directed mutagenesis; uricase.