Dorfin-CHIP chimeric proteins potently ubiquitylate and degrade familial ALS-related mutant SOD1 proteins and reduce their cellular toxicity

The ubiquitin-proteasome system (UPS) is involved in the pathogenetic mechanisms of neurodegenerative disorders, including amyotrophic lateral sclerosis (ALS). Dorfin is a ubiquitin ligase (E3) that degrades mutant SOD1 proteins, which are responsible for familial ALS. Although Dorfin has potential as an anti-ALS molecule, its life in cells is short. To improve its stability and enhance its E3 activity, we developed chimeric proteins containing the substrate-binding hydrophobic portion of Dorfin and the U-box domain of the carboxyl terminus of Hsc70-interacting protein (CHIP), which has strong E3 activity through the U-box domain. All the Dorfin-CHIP chimeric proteins were more stable in cells than was wild-type Dorfin (Dorfin(WT)). One of the Dorfin-CHIP chimeric proteins, Dorfin-CHIP(L), ubiquitylated mutant SOD1 more effectively than did Dorfin(WT) and CHIP in vivo, and degraded mutant SOD1 protein more rapidly than Dorfin(WT) does. Furthermore, Dorfin-CHIP(L) rescued neuronal cells from mutant SOD1-associated toxicity and reduced the aggresome formation induced by mutant SOD1 more effectively than did Dorfin(WT).     

Familial amyotrophic lateral sclerosis and Cu/Zn superoxide dismutase mutation

Amyotrophic lateral sclerosis (ALS) is a devastating neurodegenerative disorder that involves mainly the motor neuron system. Five to 10 percent of the ALS cases are familial; most others are sporadic. Several mutations in the superoxide dismutase-1 (SOD1) gene have recently been shown to be associated with about 20% of familial ALS patients. The reduced enzyme activity of many mutant SOD1 points to the possibility that a loss-of-function effect of the mutant enzyme is responsible for the pathogenesis of the disease. However, this conflicts with the autosomal dominant inheritance of SOD1 mutation-associated ALS and the normal SOD1 activity in homozygous patients in a SOD1-linked ALS family. Current biochemical investigations have provided evidence that mutant SOD1 may catalyze the peroxynitrite-mediated nitration of protein tyrosine residues, release copper and zinc ions, facilitate apoptosis of neurons and have enhanced peroxidase activity. Immunocytochemical studies demonstrated the presence of intense SOD1 immunoreactivity in Lewy body-like inclusions, which are characteristic features of a certain form of familial ALS with posterior column involvement, in the lower motor neurons of patients in ALS families with different SOD1 mutations. More recently, strains of transgenic mice expressing mutant SOD1 have been established. These mice clinicopathologically develop a motor neuron disease mimicking human ALS with the exception of pronounced intraneuronal vacuolar degeneration. The overexpression of wild-type SOD1 in mice has failed to give rise to the disease. Only one transgene for mutant SOD1 is enough to cause motor neuron degeneration and the severity of clinical course correlates with the transgene copy number. These observations in SOD1-linked familial ALS and its transgenic mouse model suggest a novel neurotoxic function of mutant SOD1.     

Transgenic mouse model for familial amyotrophic lateral sclerosis with superoxide dismutase‐1 mutation

Familial amyotrophic lateral sclerosis (ALS) with mutations in the gene for superoxide dismutase‐1 (SOD1) is clinicopathologically reproduced by transgenic mice expressing mutant forms of SOD1 detectable in familial ALS patients. Motor neuron degeneration associated with SOD1 mutation has been thought to result from a novel neurotoxicity of mutant SOD1, but not from a reduction in activity of this enzyme, based on autosomal dominant transmission of SOD1 mutant familial ALS and its transgenic mouse model, clinical severity of the ALS patients independent to enzyme activity, no ALS‐like disease in SOD1 knockout or wild‐type SOD1‐over‐expressing mice, and clinicopathological severity of mutant SOD1 transgenic mice dependent on transgene copy numbers. Proposed mechanisms of motor neuron de‐generation such as oxidative injury, peroxynitrite toxicity, cytoskeletal disorganization, glutamate excitotoxicity, disrupted calcium homeostasis, SOD1 aggregation, car‐bonyl stress and apoptosis have been discussed. Intracy‐toplasmic vacuoles, indicative of increased oxidative damage to the mitochondria and endoplasmic reticulum, in the neuropil and motor neurons appear in high expressors of mutant SOD1 transgenic mice but not in low expressors of the mice or familial ALS patients, suggesting that overexpression of mutant SOD1 in mice may enhance oxidative stress generation from this enzyme. Thus, transgenic mice carrying small transgene copy numbers of mutant SOD1 would provide a beneficial animal model for SOD1 mutant familial ALS. Such a model would contribute to elucidating the pathomechanism of this disease and establishing new therapeutic agents.     

Peripherin is not a contributing factor to motor neuron disease in a mouse model of amyotrophic lateral sclerosis caused by mutant superoxide dismutase

Peripherin is a type III intermediate filament protein detected in axonal spheroids associated with amyotrophic lateral sclerosis (ALS). The overexpression of peripherin induces degeneration of spinal motor neurons during aging in transgenic mice and in cultured neuronal cells derived from peripherin transgenic embryos. Here, we investigated whether peripherin is a contributor of pathogenesis in mice overexpressing a mutant superoxide dismutase 1 (SOD1(G37R)) gene linked to familial ALS. This was done by the generation and analysis of SOD1(G37R) mice that either overexpress a peripherin transgene (G37R;TgPer mice) or lack the endogenous peripherin gene (G37R;Per-/- mice). Surprisingly, upregulation or suppression of peripherin expression had no effects on disease onset, mortality, and loss of motor neurons in SOD1(G37R) mice. These results provide compelling evidence that peripherin is not a key contributor of motor neuron degeneration associated with toxicity of mutant SOD1.     

Mitochondria in amyotrophic lateral sclerosis: a trigger and a target

Strong evidence shows that mitochondrial dysfunction is involved in amyotrophic lateral sclerosis (ALS), but despite the fact that mitochondria play a central role in excitotoxicity, oxidative stress and apoptosis, the intimate underlying mechanism linking mitochondrial defects to motor neuron degeneration in ALS still remains elusive. Morphological and functional abnormalities occur in mitochondria in ALS patients and related animal models, although their exact nature and extent are controversial. Recent studies postulate that the mislocalization in mitochondria of mutant forms of copper-zinc superoxide dismutase (SOD1), the only well-documented cause of familial ALS, may account for the toxic gain of function of the enzyme, and hence induce motor neuron death. On the other hand, mitochondrial dysfunction in ALS does not seem to be restricted only to motor neurons as it is also present in other tissues, particularly the skeletal muscle. The presence of this 'systemic' defect in energy metabolism associated with the disease is supported in skeletal muscle tissue by impaired mitochondrial respiration and overexpression of uncoupling protein 3. In addition, the lifespan of transgenic mutant SOD1 mice is increased by a highly energetic diet compensating both the metabolic defect and the motorneuronal function. In this review, we will focus on the mitochondrial dysfunction linked to ALS and the cause-and-effect relationships between mitochondria and the pathological mechanisms thought to be involved in the disease.     

Inhibition of p38 mitogen activated protein kinase activation and mutant SOD1(G93A)-induced motor neuron death

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disorder characterized by the selective loss of motor neurons. Stress activated protein kinases (SAPK) have been suggested to play a role in the pathogenesis of ALS. We studied the relevance of p38 MAPK for motor neuron degeneration in the mutant SOD1 mouse. Increased levels of phospho-p38 MAPK were present in the motor neurons and microglia of the ventral spinal cord. The p38 MAPK-inhibitor, SB203580, completely inhibited mutant SOD1-induced apoptosis of motor neurons and blocked LPS-induced activation of microglia. Semapimod, a p38 MAPK inhibitor suitable for clinical use, prolonged survival of mutant SOD1 mice to a limited extent, but largely protected motor neurons and proximal axons from mutant SOD1-induced degeneration. Our data confirm the abnormal activation of p38 MAPK in mutant SOD1 mice and the involvement of p38 MAPK in mutant SOD1-induced motor neuron death. We demonstrate the effect of p38 MAPK inhibition on survival of mutant SOD1 mice and reveal a dissociation between the effect on survival of motor neurons and that on survival of the animal, the latter likely depending on the integrity of the entire motor axon.     

Spinal inhibitory interneuron pathology follows motor neuron degeneration independent of glial mutant superoxide dismutase 1 expression in SOD1-ALS mice

Motor neuron degeneration and skeletal muscle denervation are hallmarks of amyotrophic lateral sclerosis (ALS), but other neuron populations and glial cells are also involved in ALS pathogenesis. We examined changes in inhibitory interneurons in spinal cords of the ALS model low-copy Gurney G93A-SOD1 (G1del) mice and found reduced expression of markers of glycinergic and GABAergic neurons, that is, glycine transporter 2 (GlyT2) and glutamic acid decarboxylase (GAD65/67), specifically in the ventral horns of clinically affected mice. There was also loss of GlyT2 and GAD67 messenger RNA-labeled neurons in the intermediate zone. Ubiquitinated inclusions appeared in interneurons before 20 weeks of age, that is, after their development in motor neurons but before the onset of clinical signs and major motor neuron degeneration, which starts from 25 weeks of age. Because mutant superoxide dismutase 1 (SOD1) in glia might contribute to the pathogenesis, we also examined neuron-specific G93A-SOD1 mice; they also had loss of inhibitory interneuron markers in ventral horns and ubiquitinated interneuron inclusions. These data suggest that, in mutant SOD1-associated ALS, pathological changes may spread from motor neurons to interneuronsin a relatively early phase of the disease, independent of the presence of mutant SOD1 in glia. The degeneration of spinal inhibitory interneurons may in turn facilitate degeneration of motor neurons and contribute to disease progression.     

Progressive spinal axonal degeneration and slowness in ALS2-deficient mice

OBJECTIVE: Homozygous mutation in the ALS2 gene and the resulting loss of the guanine exchange factor activity of the ALS2 protein is causative for autosomal recessive early-onset motor neuron disease that is thought to predominantly affect upper motor neurons. The goal of this study was to elucidate how the motor system is affected by the deletion of ALS2. METHODS: ALS2-deficient mice were generated by gene targeting. Motor function and upper and lower motor neuron pathology were examined in ALS2-deficient mice and in mutant superoxide dismutase 1 (SOD1) mice that develop ALS-like disease from expression of an ALS-linked mutation in SOD1. RESULTS: ALS2-deficient mice demonstrated progressive axonal degeneration in the lateral spinal cord that is also prominent in mutant SOD1 mice. Despite the vulnerability of these spinal axons, lower motor neurons in ALS2-deficient mice were preserved. Behavioral studies demonstrated slowed movement without muscle weakness in ALS2(-/-) mice, consistent with upper motor neuron defects that lead to spasticity in humans. INTERPRETATION: The combined evidence from mice and humans shows that deficiency in ALS2 causes an upper motor neuron disease that in humans closely resembles a severe form of hereditary spastic paralysis, and that is quite distinct from amyotrophic lateral sclerosis.     

Altered immunoreactivity of ErbB4, a causative gene product for ALS19, in the spinal cord of patients with sporadic ALS

ErbB4 is the protein implicated in familial amyotrophic lateral sclerosis (ALS), designated as ALS19. ErbB4 is a receptor tyrosine kinase activated by its ligands, neuregulins (NRG), and plays an essential role in the function and viability of motor neurons. Mutations in the ALS19 gene lead to the reduced autophosphorylation capacity of the ErbB4 protein upon stimulation with NRG‐1, suggesting that the disruption of the NRG–ErbB4 pathway causes motor neuron degeneration. We used immunohistochemistry to study ErbB4 in the spinal cord of patients with sporadic ALS (SALS) to test the hypothesis that ErbB4 may be involved in the pathogenesis of SALS. ErbB4 was specifically immunoreactive in the cytoplasm of motor neurons in the anterior horns of the spinal cord. In patients with SALS, some of the motor neurons lost immunoreactivity with ErbB4, with the proportion of motor neurons with a loss of immunoreactivity correlated with the severity of motor neuron loss. The subcellular localization was altered, demonstrating nucleolar or nuclear localization, threads/dots and spheroids. The ectopic glial immunoreactivity was observed, mainly in the oligodendrocytes of the lateral columns and anterior horns. The reduction in the ErbB4 immunoreactivity was significantly correlated with the cytoplasmic mislocalization of transactivation response DNA‐binding protein 43 kDa (TDP‐43) in the motor neurons. No alteration in immunoreactivity was observed in the motor neurons of mice carrying atransgene for mutant form of the superoxide dismutase 1 gene (SOD1). This study provided compelling evidence that ErbB4 is also involved in the pathophysiology of SALS, and that the disruption of the NRG–ErbB4 pathway may underlie the TDP‐43‐dependent motor neuron degeneration in ALS.     

Nuclear localization of human SOD1 and mutant SOD1-specific disruption of survival motor neuron protein complex in transgenic amyotrophic lateral sclerosis mice

Amyotrophic lateral sclerosis (ALS) is a fatal adult-onset neurodegenerative disease that causes degeneration of motor neurons and paralysis. Approximately 20% of familial ALS cases have been linked to mutations in the copper/zinc superoxide dismutase (SOD1) gene, but it is unclear how mutations in the protein result in motor neuron degeneration. Transgenic (tg) mice expressing mutated forms of human SOD1 (hSOD1) develop clinical and pathological features similar to those of ALS. We used tg mice expressing hSOD1-G93A, hSOD1-G37R, and hSOD1-wild-type to investigate a new subcellular pathology involving mutant hSOD1 protein prominently localizing to the nuclear compartment and disruption of the architecture of nuclear gems. We developed methods for extracting relatively pure cell nucleus fractions from mouse CNS tissues and demonstrate a low nuclear presence of endogenous SOD1 in mouse brain and spinal cord, but prominent nuclear accumulation of hSOD1-G93A, -G37R, and -wild-type in tg mice. The hSOD1 concentrated in the nuclei of spinal cord cells, particularly motor neurons, at a young age. The survival motor neuron protein (SMN) complex is disrupted in motor neuron nuclei before disease onset in hSOD1-G93A and -G37R mice; age-matched hSOD1-wild-type mice did not show SMN disruption despite a nuclear presence. Our data suggest new mechanisms involving hSOD1 accumulation in the cell nucleus and mutant hSOD1-specific perturbations in SMN localization with disruption of the nuclear SMN complex in ALS mice and suggest an overlap of pathogenic mechanisms with spinal muscular atrophy.     

The neuroprotective factor Wlds does not attenuate mutant SOD1-mediated motor neuron disease

Selective degeneration and death of motor neurons in SOD1 mutant-mediated amyotrophic lateral sclerosis (ALS) is accompanied by axonal disorganization and reduced slow axonal transport in the three most frequently used mouse models of mutant SOD1-mediated ALS. To test whether suppression of axonal degeneration (frequently known as Wallerian degeneration) could slow disease development, we took advantage of a spontaneous mouse mutant Wld(s) (Wallerian degeneration slow) in which the programmed axonal degenerative process that is normally activated after axonal injury is significantly delayed. Despite its effectiveness in delaying axonal loss in other neurodegenerative models, the presence of Wld(s) did not slow disease onset, ameliorate mutant motor neuron death, axonal degeneration, or preserve synaptic attachments in mice that develop disease from ALS-linked SOD1 mutants SOD1G37R or SOD1G85R. However, presynaptic endings in both the presence and absence of Wld(s) showed high accumulations of mitochondria and synaptic vesicles, implicating errors of retrograde transport as a consequence of SOD1-mutant damage to axons.     

Protective effects of heat shock protein 27 in a model of ALS occur in the early stages of disease progression

Amyotrophic lateral sclerosis (ALS) is a fatal neuromuscular disorder, characterised by progressive motor neuron degeneration and muscle paralysis. Heat shock proteins (HSPs) have significant cytoprotective properties in several models of neurodegeneration. To investigate the therapeutic potential of heat shock protein 27 (HSP27) in a mouse model of ALS, we conducted an extensive characterisation of transgenic mice generated from a cross between HSP27 overexpressing mice and mice expressing mutant superoxide dismutase (SOD1(G93A)). We report that SOD1(G93A)/HSP27 double transgenic mice showed delayed decline in motor strength, a significant improvement in the number of functional motor units and increased survival of spinal motor neurons compared to SOD1(G93A) single transgenics during the early phase of disease. However, there was no evidence of sustained neuroprotection affecting long-term survival. Marked down-regulation of HSP27 protein occurred during disease progression that was not associated with a reduction in HSP27 mRNA, indicating a translational dysfunction due to the presence of mutant SOD1 protein. This study provides further support for the therapeutic potential of HSPs in ALS and other motor neuron disorders.     

Mutant SOD1 instability: implications for toxicity in amyotrophic lateral sclerosis

The biological basis of preferential motor neuron degeneration in amyotrophic lateral sclerosis (ALS) remains incompletely understood, and effective therapies to prevent the lethal consequences of this disorder are not yet available. Since 1993, more than 100 mutant variants of the antioxidant enzyme Cu/Zn superoxide dismutase (SOD1) have been identified in familial ALS. Many studies have sought to distinguish abnormal properties shared by these proteins that may contribute to their toxic effects and cause age-dependent motor neuron loss. Complex networks of cellular interactions and changes associated with aging may link mutant SOD1s and other stresses to motor neuron death in ALS. Our laboratory and collaborators have compared physicochemical properties of biologically metallated wild-type and mutant SOD1 proteins to discern specific vulnerabilities that may be relevant to the mutant toxicity in vivo. X-ray crystal structures obtained from metallated 'wild-type-like' (WTL) SOD1 mutants, which retain the ability to bind copper and zinc and exhibit normal specific activity, indicate a native-like structure with only subtle changes to the backbone fold. In contrast, a group of 'metal-binding region' (MBR) SOD1 mutants that are deficient in copper and zinc exhibit severe thermal destabilization and structural disorder of conserved loops near the metal-binding sites. A growing body of evidence highlights specific stresses in vivo that may perturb well-folded, metallated SOD1 variants and thereby favor an increased burden of partially unfolded, metal-deficient species. For example, WTL SOD1 mutants are more susceptible than wild-type SOD1 to reduction of the intrasubunit disulfide bond between Cys-57 and Cys-146 at physiological pH and temperature. This bond anchors the disulfide loop to the SOD1 beta-barrel and helps to maintain the dimeric configuration of the protein. Cleavage of the disulfide linkage renders the well-folded WTL mutants vulnerable to metal loss and monomerization such that they may resemble the destabilized and locally misfolded MBR mutant species. SOD1 proteins with disordered loops or monomeric structure are expected to be more susceptible to aberrant self-association or detrimental interactions with other cellular constituents. The challenge for future investigations is to relate these abnormal properties of partially unfolded SOD1 to specific mechanisms of toxicity in motor neurons, supporting cells, or target tissues.     

Cu/Zn-superoxide dismutase (GLY93-->ALA) mutation alters AMPA receptor subunit expression and function and potentiates kainate-mediated toxicity in motor neurons in culture

The cause of the selective degeneration of motor neurons in amyotrophic lateral sclerosis (ALS) remains a mystery. One potential pathogenic mechanism is excitotoxicity due to disturbances of glutamatergic neurotransmission, particularly via AMPA-sensitive glutamate receptors. We report here that motor neurons from a familial ALS-linked superoxide dismutase (SOD1) mutant G93A mouse show an higher susceptibility to kainate-induced excitotoxicity. Moreover, they expressed GluR(3) and GluR(4) mRNA at detectable levels more frequently, with a modified electrophysiology when compared with control and wild-type SOD1 motor neurons. Thus, the SOD1 G93A mutation causes changes in the AMPA-receptor expression and function, as well as a susceptibility to kainate-mediated excitotoxicity, which may promote the motor neuron degeneration seen in ALS.     

Apoptosis‐Inducing Factor and Cyclophilin A Cotranslocate to the Motor Neuronal Nuclei in Amyotrophic Lateral Sclerosis Model Mice

Aims: Amyotrophic lateral sclerosis (ALS) is a fatal motor neuron disease whose mechanism is not understood. Recently, it was reported that apoptosis‐inducing factor (AIF) was involved in motor neuronal cell death in ALS model mice, and AIF‐induced neuronal cell death by interacting with cyclophilin A (CypA). However, it is unknown whether the CypA and AIF‐complex induces chromatinolysis in ALS. Therefore, in the present study, we investigated the process of motor neuron degeneration as the disease progresses and to determine whether the CypA‐AIF complex would play a role in inducing motor neuronal cell death in mutant superoxide dismutase 1 (SOD1)^G93A ALS model mice. Methodology: We prepared the nuclear fractions of spinal cords and demonstrated the nuclear translocation of CypA with AIF in SOD1^G93A mice by immunoprecipitation. The localization of CypA and AIF in the spinal cords was assessed by immunohistochemistry. Results: In the spinal cords of SOD1^G93A mice, the expressions of CypA and AIF were detected in the motor neurons, and CypA and AIF cotranslocated to the motor neuronal nuclei with CypA. Furthermore, the expression of CypA was detected in GFAP‐positive astrocytes, but not in CD11b‐positive microglial cells. On the other hand, these findings were not detected in the spinal cords of wild‐type mice. Conclusions: From these results, we suggest that CypA and AIF may play cooperative and pivotal roles in motor neuronal death in the murine ALS model.     

Cytoskeletal abnormalities in amyotrophic lateral sclerosis: beneficial or detrimental effects?

Cytoskeletal abnormalities have been reported in cases of amyotrophic lateral sclerosis (ALS) including abnormal inclusions containing neurofilaments (NFs) and/or peripherin, reduced mRNA levels for the NF light (NF-L) protein and mutations in the NF heavy (NF-H) gene. Recently, transgenic mouse approaches have been used to address whether cytoskeletal changes may contribute to motor neuron disease. Mice lacking one of the three NF subunits are viable and do not develop motor neuron disease. Nonetheless, mice with null mutations for NF-L or for both NF-M and NF-H genes developed severe atrophy of ventral and dorsal root axons. The atrophic process is associated with hind limb paralysis during aging in mice deficient for both NF-M and NF-H proteins. The overexpression in mice of transgenes coding for wild-type or mutant NF proteins can provoke abnormal NF accumulations, axonal atrophy and sometimes motor dysfunction. However, the perikaryal NF accumulations are generally well tolerated by motor neurons and, except for expression of a mutant NF-L transgene, they did not provoke massive motor neuron death. Increasing the levels of perikaryal NF proteins may even confer protection in motor neuron disease caused by ALS-linked mutations in the superoxide dismutase (SOD1). In contrast, the overexpression of wild-type peripherin, a type of IF gene upregulated by inflammatory cytokines, provoked the formation of toxic IF inclusions with the high-molecular-weight NF proteins resulting in the death of motor neurons during aging. These results together with the detection of peripherin inclusions at early stage of disease in mice expressing mutant SOD1 suggest that IF inclusions containing peripherin may play a contributory role in ALS pathogenesis.     

Treatment with edaravone, initiated at symptom onset, slows motor decline and decreases SOD1 deposition in ALS mice

Edaravone is a free-radical scavenger, an agent being widely used for cerebral ischemia in Japan. To evaluate its efficacy for possible treatment of amyotrophic lateral sclerosis (ALS), we performed a randomized blind trial in ALS model mice. After identification of the clinical onset in each female G93A mutant SOD1 transgenic mouse, we intraperitoneally administered multiple doses of edaravone to the mice and observed their motor symptoms. We also counted the number of lumbar motoneurons, determined the 3-nitrotyrosine/tyrosine ratio, and evaluated the abnormal SOD1 aggregation in the spinal cord at the 10th day after the edaravone injection. Edaravone significantly slowed the motor decline of the transgenic mice. The remaining motoneurons were significantly preserved in the higher-dose edaravone-administered group, and the 3-nitrotyrosine/tyrosine ratios were reduced dose-dependently. Intriguingly, the area of abnormal SOD1 deposition in the spinal cord was significantly decreased in the higher-dose edaravone-administered group. Our results indicate that edaravone was effective to slow symptom progression and motor neuron degeneration in the ALS model mice. These favorable actions might be attributable to the yet unidentified mechanism responsible for reducing the deposition of mutant SOD1.     

In vivo pathogenic role of mutant SOD1 localized in the mitochondrial intermembrane space

Mutations in Cu,Zn superoxide dismutase (SOD1) are associated with familial amyotrophic lateral sclerosis (ALS). Mutant SOD1 causes a complex array of pathological events, through toxic gain of function mechanisms, leading to selective motor neuron degeneration. Mitochondrial dysfunction is among the well established toxic effects of mutant SOD1, but its mechanisms are just starting to be elucidated. A portion of mutant SOD1 is localized in mitochondria, where it accumulates mostly on the outer membrane and inside the intermembrane space (IMS). Evidence in cultured cells suggests that mutant SOD1 in the IMS causes mitochondrial dysfunction and compromises cell viability. Therefore, to test its pathogenic role in vivo we generated transgenic mice expressing G93A mutant or wild-type (WT) human SOD1 targeted selectively to the mitochondrial IMS (mito-SOD1). We show that mito-SOD1 is correctly localized in the IMS, where it oligomerizes and acquires enzymatic activity. Mito-G93ASOD1 mice, but not mito-WTSOD1 mice, develop a progressive disease characterized by body weight loss, muscle weakness, brain atrophy, and motor impairment, which is more severe in females. These symptoms are associated with reduced spinal motor neuron counts and impaired mitochondrial bioenergetics, characterized by decreased cytochrome oxidase activity and defective calcium handling. However, there is no evidence of muscle denervation, a cardinal pathological feature of ALS. Together, our findings indicate that mutant SOD1 in the mitochondrial IMS causes mitochondrial dysfunction and neurodegeneration, but per se it is not sufficient to cause a full-fledged ALS phenotype, which requires the participation of mutant SOD1 localized in other cellular compartments.