Comparative analysis of the protein folding activities of two chaperonin subunits of Thermococcus strain KS-1: the effects of beryllium fluoride.

We conducted a comparative analysis of the effects of beryllium fluoride (BeFx) on protein folding mediated by the alpha- and beta-subunit homooligomers (alpha16mer or beta16mer) from the hyperthermophilic archaeum Thermococcus strain KS-1. BeFx inhibited the ATPase activities of both alpha16mer and beta16mer with equal efficiency. This indicated that BeFx replaces the gamma-phosphate of chaperonin-bound ATP, thereby forming a stable chaperonin-ADP-BeFx complex. In the presence of ATP and BeFx, both of the two chaperonin subunits mediated green fluorescent protein (GFP) folding. Gel filtration chromatography revealed that the refolded GFP was retained by both chaperonins. Protease digestion and electron microscopic analyses showed that both chaperonin-ADP-BeFx complexes of the two subunits adopted a symmetric closed conformation with the built-in lids of both rings closed and that protein folding took place in their central cavities. These data indicated that basic protein folding mechanisms of alpha16mer and beta16mer are likely similar although there were some apparent differences. While beta16mer-mediated GFP refolding in the presence of ATP-BeFx that proceeded more rapidly than in the presence of ATP alone and reached a twofold higher plateau than that achieved with AMP-PNP, the folding mediated by the alpha16mer that proceeded with much lower yields. A mutant of alpha16mer, trapalpha, which traps the unfolded and partially folded substrate protein, did not affect the ATP-BeFx-dependent GFP folding by beta16mer but it suppressed that mediated by alpha16mer to the level of spontaneous folding. These results suggested that beta16mer differed from the alpha16mer in nucleotide binding affinity or the rate of nucleotide hydrolysis.

An engineered chaperonin caging a guest protein: Structural insights and potential as a protein expression tool.

The structure of a chaperonin caging a substrate protein is not quite clear. We made engineered group II chaperonins fused with a guest protein and analyzed their structural and functional features. Thermococcus sp. KS-1 chaperonin alpha-subunit (TCP) which forms an eightfold symmetric double-ring structure was used. Expression plasmids were constructed which carried two or four TCP genes ligated head to tail in phase and a target protein gene at the 3' end of the linked TCP genes. Electron microscopy showed that the expressed gene products with the molecular sizes of ~120 kDa (di-TCP) and ~230 kDa (tetra-TCP) formed double-ring complexes similar to those of wild-type TCP. The tetra-TCP retained ATPase activity and its thermostability was significantly higher than that of the wild type. A 260-kDa fusion protein of tetra-TCP and green fluorescent protein (GFP, 27 kDa) was able to form the double-ring complexes with green fluorescence. Image analyses indicated that the GFP moiety of tetra-TCP/GFP fusion protein was accommodated in the central cavity, and tetra-TCP/GFP formed the closed-form similar to that crystallographically resolved in group II chaperonins. Furthermore, it was suggested that caging GFP expanded the cavity around the bottom. Using this tetra-TCP fusion strategy, two virus structural proteins (21-25 kDa) toxic to host cells or two antibody fragments (25-36 kDa) prone to aggregate were well expressed in the soluble fraction of Escherichia coli. These fusion products also assembled to double-ring complexes, suggesting encapsulation of the guest proteins. The antibody fragments liberated by site-specific protease digestion exhibited ligand-binding activities.