High activity chimeric snake gamma-type phospholipase A2 inhibitor created by DNA shuffling.

Abstract The gamma-type inhibitor of snake venom phospholipase A 2 (PLIγ) is expressed extensively in livers of both venomous and non-venomous snakes. It is not clear why PLIγs from different snake species possess diverse activities. To obtain high activity PLIγs and interpret the sequence-function relationships, we used DNA shuffling to hybridize the PLIγs of Sinonatrix annularis (saPLIγ) and Elaphe carinata (ecPLIγ). Chimera PLIγs (cPLIγ) of ∼550 bp were obtained by a series of gene manipulations including DNase I digestion, primer-free PCR, and PCR amplification with PLIγs primer pair. After successful insertion of cPLIγs into pCANTAB5e phage vector, the transformed TG1 strain of Esherichia coli was achieved. The cPLIγ phage library was produced and panned in a five-pace snake venom-coated immune tube. Three high affinity cPLIγ isoforms survived two rounds of panning. Prokaryote expression by the pET28c vector was employed for production of the three cPLIγs and the two parental PLIγs. These all showed anti-hemorrhage activity with cPLIγ 2 demonstrating superior inhibition to the parent PLIγs. Sequence alignment showed that the three kinds of cPLIγ were produced by gene splicing of S. annularis and E. carinata at different sites. Primary sequence changes brought regional changes in secondary and tertiary structure, which may explain the differences in PLIγ activity. Highlights • PLIγ can neutralize snake venom PLA2s, and is regarded as a promising antivenom candidate. • DNA shuffling and phage surface display is an effective way for PLIγ directed evolution. • The chimera PLIγ 2 showed even superior anti-hemorrhage activity than the parent PLIγs. • The α-helix of 150–155aa was believed to be correlative to the activity of PLIγ. [ABSTRACT FROM AUTHOR]