David Alsina, Joaquim Ros, Jordi Tamarit, Redox Biology, Available online 6 September 2017, ISSN 2213-2317, doi:10.1016/j.redox.2017.09.001.
A major conclusion of this work is that Yfh1 deficiency activates the
iron regulon by a different pathway than iron-sulfur loss. Therefore,
alternative pathways for Aft1 activation may exist in yeast which, as
discussed above, could be related to the presence of anomalous iron
species. We have also observed that metabolic status can be efficiently
monitored using a targeted proteomics strategy focusing on key metabolic
enzymes. Finally, the observation that NO can mitigate the defects
caused by Yfh1 deficiency supports the hypothesis that Yfh1 loss leads
to the increased presence of anomalous iron forms, and that this
anomalous iron plays a central role in the events caused by Yfh1
deficiency. It also suggests that NO donors could have a therapeutic
effect in FRDA patients. NO donors such as SNP or nitroglycerin have
been used for more than a century for controlling congestive heart
failure associated with heart attack or lowering blood pressure during
surgery.
Beyond its vasodilating action, neuroprotective properties have been
demonstrated for NO in an iron-induced model of Parkinson's disease.
This observation, together with the results presented in this work,
opens the possibility to explore the potential therapeutic effect of NO
donors in mammalian models of FRDA.
Nitric oxide prevents Aft1 activation and metabolic remodeling in Frataxin-deficient yeast