Mitochondrial matrix proteostasis is linked to hereditary paraganglioma: LON-mediated turnover of the human flavinylation factor SDH5 is regulated by its interaction with SDHA

Abstract

Mutations in succinate dehydrogenase (SDH) subunits and assembly factors cause a range of clinical conditions. One such condition, hereditary paraganglioma 2 (PGL2), is caused by a G78R mutation in the assembly factor SDH5. Although SDH5G78R is deficient in its ability to promote SDHA flavinylation, it has remained unclear whether impairment to its import, structure, or stability contributes to its loss of function. Using import-chase analysis in human mitochondria isolated from HeLa cells, we found that the import and maturation of human SDH5G78R was normal, while its stability was reduced significantly, with ∼25% of the protein remaining after 180 min compared to ∼85% for the wild-type protein. Notably, the metabolic stability of SDH5G78R was restored to wild-type levels by depleting mitochondrial LON (LONM). Degradation of SDH5G78R by LONM was confirmed in vitro; however, in contrast to the in organello analysis, wild-type SDH5 was also rapidly degraded by LONM. SDH5 instability was confirmed in SDHA-depleted mitochondria. Blue native PAGE showed that imported SDH5G78R formed a transient complex with SDHA; however, this complex was stabilized in LONM depleted mitochondria. These data demonstrate that SDH5 is protected from LONM-mediated degradation in mitochondria by its stable interaction with SDHA, a state that is dysregulated in PGL2.—Bezawork-Geleta, A., Saiyed, T., Dougan, D. A., Truscott, K. N. Mitochondrial matrix proteostasis is linked to hereditary paraganglioma: LON-mediated turnover of the human flavinylation factor SDH5 is regulated by its interaction with SDHA.