Hélène Puccio

Mouse models for Friedreich ataxia exhibit cardiomyopathy, sensory nerve defect and Fe-S enzyme deficiency followed by intramitochondrial iron deposits

Friedreich ataxia (FRDA), the most common autosomal recessive ataxia, is characterized by degeneration of the large sensory neurons and spinocerebellar tracts, cardiomyopathy and increased incidence in diabetes. FRDA is caused by severely reduced levels of frataxin, a mitochondrial protein of unknown function. Yeast knockout models as well as histological and biochemical data from heart biopsies or autopsies of FRDA patients have shown that frataxin defects cause a specific iron-sulfur protein deficiency and intramitochondrial iron accumulation. We have recently shown that complete absence of frataxin in the mouse leads to early embryonic lethality, demonstrating an important role for frataxin during mouse development. Through a conditional gene-targeting approach, we have generated in parallel a striated muscle frataxin-deficient line and a neuron/cardiac muscle frataxin-deficient line, which together reproduce important progressive pathophysiological and biochemical features of the human disease: cardiac hypertrophy without skeletal muscle involvement, large sensory neuron dysfunction without alteration of the small sensory and motor neurons, and deficient activities of complexes I–III of the respiratory chain and of the aconitases. Our models demonstrate time-dependent intramitochondrial iron accumulation in a frataxin-deficient mammal, which occurs after onset of the pathology and after inactivation of the Fe-S-dependent enzymes. These mutant mice represent the first mammalian models to evaluate treatment strategies for the human disease.

Friedreich ataxia: a paradigm for mitochondrial diseases

Friedreich ataxia (FRDA), a progressive neurodegenerative disease, is due to the partial loss of function of frataxin, a mitochondrial protein of unknown function. Loss of frataxin causes mitochondrial iron accumulation, deficiency in the activities of iron-sulfur (Fe-S) proteins, and increased oxidative stress. Mouse models for FRDA demonstrate that the Fe-S deficit precedes iron accumulation, suggesting that iron accumulation is a secondary event. Furthermore, increased oxidative stress in FRDA patients has been demonstrated, and in vitro experiments imply that the frataxin defect impairs early antioxidant defenses. These results taken together suggest that frataxin may function either in mitochondrial iron homeostasis, in Fe-S cluster biogenesis, or directly in the response to oxidative stress. It is clear, however, that the pathogenic mechanism in FRDA involves free-radical production and oxidative stress, a process that appears to be sensitive to antioxidant therapies.

Limitations in a frataxin knockdown cell model for Friedreich ataxia in a high-throughput drug screen

BackgroundPharmacological high-throughput screening (HTS) represents a powerful strategy for drug discovery in genetic diseases, particularly when the full spectrum of pathological dysfunctions remains unclear, such as in Friedreich ataxia (FRDA). FRDA, the most common recessive ataxia, results from a generalized deficiency of mitochondrial and cytosolic iron-sulfur cluster (ISC) proteins activity, due to a partial loss of frataxin function, a mitochondrial protein proposed to function as an iron-chaperone for ISC biosynthesis. In the absence of measurable catalytic function for frataxin, a cell-based assay is required for HTS assay.MethodsUsing a targeted ribozyme strategy in murine fibroblasts, we have developed a cellular model with strongly reduced levels of frataxin. We have used this model to screen the Prestwick Chemical Library, a collection of one thousand off-patent drugs, for potential molecules for FRDA.ResultsThe frataxin deficient cell lines exhibit a proliferation defect, associated with an ISC enzyme deficit. Using the growth defect as end-point criteria, we screened the Prestwick Chemical Library. However no molecule presented a significant and reproducible effect on the proliferation rate of frataxin deficient cells. Moreover over numerous passages, the antisense ribozyme fibroblast cell lines revealed an increase in frataxin residual level associated with the normalization of ISC enzyme activities. However, the ribozyme cell lines and FRDA patient cells presented an increase in Mthfd2 transcript, a mitochondrial enzyme that was previously shown to be upregulated at very early stages of the pathogenesis in the cardiac mouse model.ConclusionAlthough no active hit has been identified, the present study demonstrates the feasibility of using a cell-based approach to HTS for FRDA. Furthermore, it highlights the difficulty in the development of a stable frataxin-deficient cell model, an essential condition for productive HTS in the future.

CHAPTER 20 – Mouse Models for Friedreich's Ataxia

This chapter focuses on several mouse models developed for Friedreichs ataxia (FRDA). Mouse models have been important tools in dissecting the steps of pathogenesis in FRDA. The neuron-specific mouse model developed a movement disorder characterized by gait abnormalities and loss of proprioception. Furthermore, electrophysiological studies revealed a specific large sensory nerve conduction defect with normal motor nerve conduction. Inducible knockout mouse models using two transgenic lines (28.4 and 28.6, having distinct neuronal specificities) expressing the tamoxifen-dependent recombinase (Cre-ER T ) under the mouse prion protein (Prp) promoter, enables one to spatiotemporally control somatic mutagenesis of conditional alleles of the targeted genes. Both Prp-Cre-ER T hues express Cre-ER T recombinase in the nervous system, but whereas the 28.4 line has a wide expression pattern, the Cre-ER T expression of the 28.6 line is mostly restricted to the hippocampus, the cerebellum, and the dorsal root ganglia (DRG). The progressive neurodegeneration of the DRG represents an excellent model for unraveling the pathological cascade leading to neuronal death in FRDA.

The molecular pathogenesis of Friedreich ataxia

Abstract Friedreich ataxia, the most frequent cause of recessive ataxia is due in most cases to a homozygous intronic expansion resulting in the loss of function of frataxin. Frataxin is a mitochondrial protein conserved through evolution. Yeast knock-out models and histological data from patients heart autopsies have shown that frataxin defect causes mitochondrial iron accumulation. Biochemical data from patients heart biopsies or autopsies have revealed a specific deficiency in the activities of aconitases and of mitochondrial iron–sulfur proteins. These results suggest that frataxin may play a role either in mitochondrial iron transport or in iron–sulfur cluster assembly or transport. Iron abnormalities suggest a pathogenic mechanism involving free radicals production and oxidative stress, a process that might be sensitive to anti-oxidant therapies.