Role of low native state kinetic stability and interaction of partially unfolded states with molecular chaperones in the mitochondrial protein mistargeting associated with primary hyperoxaluria

Abstract

The G170R variant of the alanine:glyoxylate aminotransferase (AGT) is the most common pathogenic allele associated to primary hyperoxaluria type I (PH1), leading to mitochondrial mistargeting when combined with the P11L and I340M polymorphisms (minor allele; AGT(LM)). In this work, we have performed a comparative analysis on the conformation, unfolding energetics and interaction with molecular chaperones between AGT(wt), AGT(LM) and AGT(LRM) (G170R in the minor allele) proteins. Our results show that these three variants share similar conformational and functional properties as folded dimers. However, kinetic stability analyses showed a ≈1,000-fold increased unfolding rate for apo-AGT(LRM) compared to apo-AGT(wt), as well as a reduced folding efficiency upon expression in Escherichia coli. Pyridoxal 5'-phosphate (PLP)-binding provided a 4-5 orders of magnitude enhancement of the kinetic stability for all variants, suggesting a role for kinetic stabilization in pyridoxine-responsive PH1. Conformational studies at mild acidic pH and moderate guanidium concentrations showed the formation of a molten-globule-like unfolding intermediate in all three variants, which do not reactivate to the native state and strongly interact with Hsc70 and Hsp90 chaperones. Additional expression analyses in a mammalian cell-free system at neutral pH showed enhanced interaction of AGT(LRM) with Hsc70 and Hsp90 proteins compared to AGT(wt), suggesting kinetic trapping of the mutant by chaperones along the folding process. Overall, our results suggest that mitochondrial mistargeting of AGT(LRM) may involve the presentation of AGT partially folded states to the mitochondrial import machinery by molecular chaperones, which would be facilitated by the low native state kinetic stability (partially corrected by PLP binding) and kinetic trapping during folding of the AGT(LRM) variant with molecular chaperones.