Minkyeong Ahn1, Sangje Park1, Junhyun Jeon1, Jung Kyu Choi1, Yongho Khang2. 1. Department of Biotechnology, Yeungnam University, Gyeongsan, 38541, Republic of Korea. 2. Department of Biotechnology, Yeungnam University, Gyeongsan, 38541, Republic of Korea. yhkhang@ynu.ac.kr.
Abstract
OBJECTIVE: To evaluate whether the surface layer (S-layer) protein of Lactobacillus brevis serves as a self-aggregating protein tag for cost-effective separation of human and yeast D-amino acid oxidases (hDAAO and yDAAO) expressed in E. coli. RESULTS: In aqueous two-phase (PEG-phosphate) system, the S-layer:DAAO fusion proteins (shDAAO and syDAAO) were separated at the interface with a recovery of 82 ± 10.6% for shDAAO and 95 ± 1.9% for syDAAO. Some shDAAO proteins were separated as precipitates with a recovery of 41 ± 0.5% in phosphate (9%, w/w) using PEG 3000 and PEG 4000 (16%, w/w), while some syDAAO proteins were also isolated as precipitates with a recovery of 75 ± 17.5% in phosphate (9%, w/w) using PEG 4000 and PEG 8000 (16%, w/w). CONCLUSIONS: The S-layer of L. brevis was applied to a self-assembled protein tag to enable cost-effective separation of human and yeast D-amino acid oxidases expressed in E. coli cells. Because of the self-assembling properties of S-layer proteins, human and yeast D-amino acid oxidases fused with S-layer proteins could be easily separated by aggregates at the interface and/or in a few conditions by precipitates to the bottom of the PEG-phosphate aqueous system.
OBJECTIVE: To evaluate whether the surface layer (S-layer) protein of Lactobacillus brevis serves as a self-aggregating protein tag for cost-effective separation of human and yeastD-amino acid oxidases (hDAAO and yDAAO) expressed in E. coli. RESULTS: In aqueous two-phase (PEG-phosphate) system, the S-layer:DAAO fusion proteins (shDAAO and syDAAO) were separated at the interface with a recovery of 82 ± 10.6% for shDAAO and 95 ± 1.9% for syDAAO. Some shDAAO proteins were separated as precipitates with a recovery of 41 ± 0.5% in phosphate (9%, w/w) using PEG 3000 and PEG 4000 (16%, w/w), while some syDAAO proteins were also isolated as precipitates with a recovery of 75 ± 17.5% in phosphate (9%, w/w) using PEG 4000 and PEG 8000 (16%, w/w). CONCLUSIONS: The S-layer of L. brevis was applied to a self-assembled protein tag to enable cost-effective separation of human and yeastD-amino acid oxidases expressed in E. coli cells. Because of the self-assembling properties of S-layer proteins, human and yeastD-amino acid oxidases fused with S-layer proteins could be easily separated by aggregates at the interface and/or in a few conditions by precipitates to the bottom of the PEG-phosphate aqueous system.