Consideration on Efficient Recombinant Protein Production: Focus on Substrate Protein-Specific Compatibility Patterns of Molecular Chaperones.

Expression of recombinant proteins requires at times the aid of molecular chaperones for efficient post-translational folding into functional structure. However, predicting the compatibility of a protein substrate with the right type of chaperone to produce functional proteins is a daunting issue. To study the difference in effects of chaperones on His-tagged recombinant proteins with different characteristics, we performed in vitro proteins expression using Escherichia coli overexpressed with several chaperone 'teams': Trigger Factor (TF), GroEL/GroES and DnaK/DnaJ/GrpE, alone or in combinations, with the aim to determine whether protein secondary structure can serve as predictor for chaperone success. Protein A, which has a helix dominant structure, showed the most efficient folding with GroES/EL or TF chaperones alone, whereas Protein B, which has less helix in the structure, showed a remarkable effect on the DnaK/J/GrpE system alone. This tendency was also seen with other recombinant proteins with particular properties. With the chaperons' assistance, both proteins were synthesized more efficiently in the culture at 22.5 °C for 20 h than at 37 °C for 3 h. These findings suggest a novel avenue to study compatibility of chaperones with substrate proteins and optimal culture conditions for producing functional proteins with a potential for predictive analysis of the success of chaperones based on the properties of the substrate protein.