Protein Engineering of Vip3A in a Selected Bacillus thuringiensis Host for Consistent High Protein Production.

Abstract

This study aimed to obtain reliable high Vip3A production from Bacillus thuringiensis (Bt) by modifying Vip3A to acquire higher thermostability in a suitable host. Bt117 is a great host for Vip3A production due to protein production consistency, low protease activity in culture media, and large amounts of mostly full-length protein, but it produces Vip3A with lower thermostability (Vip3Aa35). The C-terminal region of Bt117 Vip3A was replaced with that of a Vip3A with higher thermostability (Vip3Aa64 from Bt294) to generate the recombinant Bt117-Vip3Aa64-C. Like the parental strain Bt117, this strain expressed mostly full-length protein and exhibited low protease activity and similar protein expression profiles in culture media but retained greater larvicidal activity upon 37°C storage like Bt294 Vip3Aa64. Importantly, every culture batch of Bt117-Vip3Aa64-C yielded over 200mg/l Vip3A, which is a notable improvement over the original Vip3Aa64-producing strain Bt294 where 45% of culture batches failed to produce Vip3A at the same level. Successfully, we combined the superior qualities of two Bt strains, Bt294, which produces thermostable Vip3A but at low and inconsistent levels, and Bt117, which produces Vip3A with low thermostability but at consistently high levels. Protein engineering of Vip3A in Bt117 ultimately yielded an improved strain producing a thermostable Vip3A with reliably high protein production.