Abstract
An efficient electrotransformation system that includes electrocompetent cells is a critical component for the success of large‐scale gene transduction and replication. The conditions of TG1 competent cell preparation and optimal electrotransformation were evaluated by investigating different parameters. Certain parameters for preparation of TG1 competent cells (≥8 × 1010 colony forming units (cfu)/μg DNA) include optimum culture time of monoclonal bacteria (8–10 hr), amplification growth concentration (approximately OD600 = 0.45), and culture volume (400 ml in 2 L conical flask). With increased storage of competent cells at −80°C, electrotransformation efficiency gradually decreased, but it remains greater than ≥ 1010 cfu/μg DNA 3 months later. Moreover, the recovery time of electrotransformation also influenced electrotransformation efficiency (1.5–2 hr for optimization). The optimized transformation efficiency of TG1 (≥8 × 1010 cfu/μg DNA) was observed under suitable electric voltage (2.5 kV), electric intensity (15 kV/cm), and electric time (3.5 ms) of electricity for plasmid transformation. Optimized DNA amount (0.01–100 ng) dissolved in water led to the high efficiency of plasmid transformation (≥8 × 1010 cfu/μg DNA), but had low efficiency when dissolved in T4 ligation buffer (≤3 × 1010 cfu/μg DNA). These results indicated that an optimized TG1 transformation system is useful for high electrotransformation efficiency under general laboratory conditions. The optimized TG1 transformation system might facilitate large‐scale gene transduction for phage display library construction.
Highlights
Phage display library has proven to be a powerful technology for screening of single-chain antibody fragment, which provides candidate sequences for the development of fully human monoclonal antibody drugs, chimeric antigen receptor (CAR)-T cell drugs, or antibody-based therapeutics (Mimmi, Maisano, Quinto, & Iaccino, 2019)
It was previously reported that the electrotransformation efficiency of E. coli is up to 108–109 cfu/μg DNA in a general laboratory (Tu et al, 2005), in which electrocompetent cells are less effective and unable to meet the requirements of large phage antibody libraries
Due to cost, transportation or electrotransformation efficiency, TG1 competent cells are unable to meet the requirement of large phage antibody display libraries in a general laboratory
Summary
Phage display library has proven to be a powerful technology for screening of single-chain antibody fragment (scFv), which provides candidate sequences for the development of fully human monoclonal antibody (mAb) drugs, chimeric antigen receptor (CAR)-T cell drugs, or antibody-based therapeutics (Mimmi, Maisano, Quinto, & Iaccino, 2019). High electro transformation efficiency of 107 cfu/μg DNA was observed in Corynebacterium glutamicum by weakening its cell wall (Li, Zhang, Guo, & Xu, 2016). These electro transformation systems are still unsatisfactory for large phage antibody libraries. It was previously reported that the electrotransformation efficiency of E. coli is up to 108–109 cfu/μg DNA in a general laboratory (Tu et al, 2005), in which electrocompetent cells are less effective and unable to meet the requirements of large phage antibody libraries. The development of a high-efficient electrotransformation system is urgently needed for phage display antibody libraries. Higher electrotransformation efficiency of the optimized TG1 transformation system could meet the need of phage display library construction
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