Abstract
The protein aggregation is one of the major challenges of the biotechnological industry, especially in the areas of development and commercialization of successful protein-based drug products. The inherent high aggregation tendency of proteins during various manufacturing processes, storage, and administration has significant impact upon the product quality, safety and efficacy. We have developed an interesting protein purification approach that separates the functionally active protein from inactive aggregates using a detergent concentration gradient. The C-terminally His tagged nucleocapsid protein of Crimean Congo Hemorrhagic fever virus (CCHFV) has high aggregation tendency and rapidly precipitates upon purification by NiNTA chromatography. Using the new purification approach reported here, the freshly purified protein by NiNTA chromatography was further processed using a detergent gradient. In this new purification approach the active protein is retained in the low detergent concentration zone while the inactive aggregates are promptly removed by their rapid migration to the high detergent concentration zone. The method prevented further aggregation and retained the RNA binding activity in the native protein despite numerous freeze thaw cycles. This simple approach prevents protein aggregation by rapidly separating the preformed early aggregates and creating the appropriate microenvironment for correctly folded proteins to retain their biological activity. It will be of potential importance to the biotechnological industry and other fields of protein biochemistry that routinely face the challenges of protein aggregation.
Highlights
A newly translated protein can adopt different types of conformational states within the cellular environment
Escherichia coli remains the dominant host for the production of recombinant proteins due to numerous advantages, such as, high yield protein production, ease of use, fast growth of the bacterial cultures, cost effectiveness, together with the well characterized genetics and a variety of available molecular tools
The recombinant proteins produced from E. coli have significantly advanced the general filed of biology and biopharmaceutical industry
Summary
A newly translated protein can adopt different types of conformational states within the cellular environment. The monomeric protein constituents of an oligomeric protein complex, and molecular chaperones that guide the co-translational folding into the native state, play critical roles in the adoption of unique biologically active and stable protein conformation [2, 3]. Failure of these guiding interactions and proteotoxic stresses such as heat shock can cause proteins to expose aggregation-prone hydrophobic regions that trigger the protein aggregation [4]. Proteins are temporarily at increased risk of aggregation during transport
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