Conformational stability of human frataxin and effect of Friedreich's ataxia-related mutations on protein folding

The neurodegenerative disorder FRDA (Friedreich's ataxia) results from a deficiency in frataxin, a putative iron chaperone, and is due to the presence of a high number of GAA repeats in the coding regions of both alleles of the frataxin gene, which impair protein expression. However, some FRDA patients are heterozygous for this triplet expansion and contain a deleterious point mutation on the other allele. In the present study, we investigated whether two particular FRDA-associated frataxin mutants, I154F and W155R, result in unfolded protein as a consequence of a severe structural modification. A detailed comparison of the conformational properties of the wild-type and mutant proteins combining biophysical and biochemical methodologies was undertaken. We show that the FRDA mutants retain the native fold under physiological conditions, but are differentially destabilized as reflected both by their reduced thermodynamic stability and a higher tendency towards proteolytic digestion. The I154F mutant has the strongest effect on fold stability as expected from the fact that the mutated residue contributes to the hydrophobic core formation. Functionally, the iron-binding properties of the mutant frataxins are found to be partly impaired. The apparently paradoxical situation of having clinically aggressive frataxin variants which are folded and are only significantly less stable than the wild-type form in a given adverse physiological stress condition is discussed and contextualized in terms of a mechanism determining the pathology of FRDA heterozygous.