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Novel folding and stability defects cause a deficiency of human glutathione transferase omega 1

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posted on 2024-11-14, 15:50 authored by Huina Zhou, Joseph Brock, Marco G Casarotto, Aaron OakleyAaron Oakley, Philip G Board
The polymorphic deletion of Glu-155 from human glutathione transferase omega1 (GSTO1-1) occurs in most populations. Although the recombinant ΔGlu-155 enzyme expressed in Escherichia coli is active, the deletion causes a deficiency of the active enzyme in vivo. The crystal structure and the folding/unfolding kinetics of the ΔGlu-155 variant were determined in order to investigate the cause of the rapid loss of the enzyme in human cells. The crystal structure revealed altered packing around the Glu-155 deletion, an increase in the predicted solvent-accessible area and a corresponding reduction in the buried surface area. This increase in solvent accessibility was consistent with an elevated Stern-Volmer constant. The unfolding of both the wild type and ΔGlu-155 enzyme in urea is best described by a three-state model, and there is evidence for the more pronounced population of an intermediate state by the ΔGlu-155 enzymes. Studies using intrinsic fluorescence revealed a free energy change around 14.4 kcal/mol for the wild type compared with around 8.6 kcal/mol for the ΔGlu-155 variant, which indicates a decrease in stability associated with the Glu-155 deletion. Urea induced unfolding of the wild type GSTO1-1 was reversible through an initial fast phase followed by a second slow phase. In contrast, the ΔGlu-155 variant lacks the slow phase, indicating a refolding defect. It is possible that in some conditions in vivo, the increased solvent-accessible area and the low stability of the ΔGlu-155 variant may promote its unfolding, whereas the refolding defect limits its refolding, resulting in GSTO1-1 deficiency.

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Citation

Zhou, H., Brock, J., Casarotto, M. G., Oakley, A. J. & Board, P. G. (2011). Novel folding and stability defects cause a deficiency of human glutathione transferase omega 1. Journal of Biological Chemistry, 286 (6), 4271-4279.

Journal title

Journal of Biological Chemistry

Volume

286

Issue

6

Pagination

4271-4279

Language

English

RIS ID

35502

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