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Solid‐Phase Refolding of Cyclodextrin Glycosyltransferase Adsorbed on Cation‐Exchange Resin
Author(s) -
Kweon DaeHyuk,
Lee DaeHee,
Han NamSoo,
Seo JinHo
Publication year - 2008
Publication title -
biotechnology progress
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.572
H-Index - 129
eISSN - 1520-6033
pISSN - 8756-7938
DOI - 10.1021/bp0341895
Subject(s) - chemistry , adsorption , yield (engineering) , ion exchange , phase (matter) , lysine , fusion protein , cyclodextrin , protein aggregation , fusion , combinatorial chemistry , chromatography , biophysics , ion , biochemistry , recombinant dna , organic chemistry , amino acid , materials science , linguistics , philosophy , biology , metallurgy , gene
Abstract Expression with a fusion partner is now a popular scheme to produce a protein of interest because it provides a generic tool for expression and purification. In our previous study, a strong polycationic tail has been harnessed for an efficient purification scheme. Here, the same polycation tail attached to a protein of interest is shown to hold versatility for a solid‐phase refolding method that utilizes a charged adsorbent as a supporting material. Cyclodextrin glycosyltransferase (CGTase) fused with 10 lysine residues at the C‐terminus (CGTK10ase) retains the ability to bind to a cation exchanger even in a urea‐denatured state. When the denatured and adsorbed CGTK10ase is induced to refold, the bound CGTK10ase aggregates little even at a g/L range. The renatured CGTK10ase can also be simply recovered from the solid support by adding high concentration of NaCl. The CGTK10ase refolded on a solid support retains specific enzyme activity virtually identical to that of the native CGTK10ase. Several factors that are important in improving the refolding efficiency are explored. Experimental results indicate that nonspecific electrostatic interactions between the charge of the ion exchanger and the local charge of CGTase other than the polycationic tag should be reduced to obtain higher refolding yield. The solid‐phase refolding method utilizing a strong polycationic tag resulted in a remarkable increase in the refolding performance. Taken together with the previous report in which a series of polycations were explored for efficient purification, expression of a target protein fused with a strong polycation provides a straightforward protein preparation scheme.

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