Nanobodies as tools for studying human frataxin biology.

Iron-sulfur clusters are essential cofactors for the accurate cellular function of many proteins. In eukaryotic cells, the biogenesis of most iron-sulfur clusters occurs in the mitochondria and involves the action of the Cys desulfurase supercomplex, which is activated by the protein frataxin (FXN). The decrease of FXN expression and/or function results in Friedreich's ataxia (FRDA).In this work, several nanobodies specific to human FXN were selected via phage display, demonstrating a wide range of effects on Cys desulfurase activity and a strong interaction with FXN. Nanobody interaction stabilized wild-type and FRDA-related FXN variants in vitro. FXN-nanobody complexes were characterized by NMR, SAXS, and X-ray crystallography. Additionally, Nanobody expression was studied in human cells. The subcellular localization, direct interaction with FXN by in situ proximity ligation assay, effect on cell viability, Fe-S-dependent enzymatic activities, and oxygen consumption rates were analyzed. Significantly, nanobody expression did not alter these key metabolic variables, suggesting that the interaction with FXN did not disrupt the pathway.As a whole, our results suggest that nanobodies can serve as binding partners for mitochondrial FXN. However, the specific effect of the nanobodies on the conformational stability of FRDA-related FXN variants in cells should be investigated.