SOD1 Knockout Mice Research Articles

Disease Progression in a Transgenic Model of Familial Amyotrophic Lateral Sclerosis Is Dependent on Both Neuronal and Non-Neuronal Zinc Binding Proteins

Mutations in the Cu/Zn superoxide dismutase (SOD1) gene cause one form of familial amyotrophic lateral sclerosis, a progressive disorder of motor neurons leading to weakness and death of affected individuals. Experiments using both transgenic mice expressing mutant SOD1 and SOD1 knock-out mice have demonstrated that disease is caused by a toxic gain of function and not by a loss of normal SOD1 activity. Precise mechanisms underlying mutant SOD1 toxicity are unclear but may involve abnormal interactions between zinc and SOD1. The metallothioneins (MTs) represent a family of zinc binding proteins that can function as zinc chaperones for apo-SOD1 in vitro. We hypothesized that manipulation of metallothioneins in vivo might alter the disease phenotype of transgenic mice expressing G93A SOD1 and therefore crossed this line with MT-I and MT-II or MT-III knock-out mice. G93A SOD1 mice deficient of either MT-I and MT-II or MT-III exhibited significant reductions in survival compared with G93A SOD1 mice. In addition, motor dysfunction was markedly accelerated in G93A SOD1 mice deficient in metallothioneins with regard to onset (MT-I and MT-II) or progression (MT-III). These results indicate that the disease course in G93A SOD1 mice is dependent on levels of metallothionein expression. Because MT-I and MT-II are expressed in glia whereas MT-III is found in neurons, these results also indicate that primary changes within non-neuronal cells can affect mutant SOD1-induced disease and do so in ways distinct from primary neuronal changes.

Postischemic recovery of contractile function is impaired in SOD2(+/-) but not SOD1(+/-) mouse hearts.

Reactive oxygen species (ROS) contribute to myocardial stunning. Superoxide dismutase (SOD) is a major defense mechanism against ROS. The purpose of this study was to evaluate the contributions of cytosolic (SOD1) and mitochondrial (SOD2) isoforms to protect against myocardial stunning. Isolated hearts from wild-type, heterozygous (+/-) SOD1 and SOD2 knockout mice received 30 minutes of ischemia followed by 60 minutes of reperfusion. After 60 minutes of reperfusion, the heart rate multiplied by the developed pressure (HRxDP) in the wild-type and SOD1(+/-) hearts recovered to 92 +/- 9 and 85 +/- 7 of preischemic baseline values, respectively (P=NS). In contrast, the HRxDP was significantly lower (63 +/- 7%) in the SOD2(+/-) hearts compared with the wild-type hearts. Western blot analysis and enzymatic activity of tissue lysates confirmed reduction of activities of specific SOD isoforms without compensatory increase in the other isoform in the knockout animals studied. Postischemic functional recovery is more sensitive to a partial deficiency of SOD2 than a partial deficiency of SOD1. Therefore, modulation of the mitochondrial SOD isoform is a critical determinant in the tolerance of the heart to oxidative stress.

Increased sensitivity of homozygous Sod2 mutant mice to oxygen toxicity

Induction or overexpression of pulmonary manganese superoxide dismutase (MnSOD) has been shown to protect against oxygen (O 2) toxicity. Genetic inactivation of MnSOD ( Sod2) results in multiple organ failure and early neonatal death. However, lungs or O 2-tolerance of Sod2 knockout mice have not been investigated. We evaluated survival, lung histopathology, and other pulmonary antioxidants (glutathione cycle) of homozygous (−/−) and heterozygous (+/−) Sod2 mutant mice compared with wild-type controls ( Sod2+/+) following 48 h exposure to either room air or to O 2. The ability of antioxidant N-acetylcysteine to compensate for the loss of MnSOD was explored. Mortality of Sod2−/− mice increased from 0% in room air to 18 and 83% in 50 and 80% O 2, respectively. N-acetylcysteine did not alter mortality of Sod2−/− mice. Histopathological analysis revealed abnormalities in saccules of Sod2−/− mice exposed either to room air or to 50% O 2 suggestive of delayed postnatal lung development. In 50% O 2, activities of glutamate-cysteine ligase (GCL) (previously known as γ-glutamylcysteine synthetase, γ-GCS) and glutathione peroxidase increased in Sod2−/− (35 and 70%, respectively) and Sod2+/− (12 and 70%, respectively) mice, but glutathione levels remained unaltered. We conclude that MnSOD is required for normal O 2 tolerance and that in the absence of MnSOD there is a compensatory increase in pulmonary glutathione-dependent antioxidant defense in hyperoxia.

Mice with a Partial Deficiency of Manganese Superoxide Dismutase Show Increased Vulnerability to the Mitochondrial Toxins Malonate, 3-Nitropropionic Acid, and MPTP

There is substantial evidence implicating mitochondrial dysfunction and free radical generation as major mechanisms of neuronal death in neurodegenerative diseases. The major free radical scavenging enzyme in mitochondria is manganese superoxide dismutase (SOD2). In the present study we investigated the susceptibility of mice with a partial deficiency of SOD2 to the neurotoxins 1-methyl-4-phenyl-1,2,5,6-tetrahydropyridine (MPTP), 3-nitropropionic acid (3-NP), and malonate, which are commonly used animal models of Parkinson's and Huntington's disease. Heterozygous SOD2 knockout (SOD2+/−) mice showed no evidence of neuropathological or behavioral abnormalities at 2–4 months of age. Compared to littermate wild-type mice, mice with partial SOD2 deficiency showed increased vulnerability to dopamine depletion after systemic MPTP treatment and significantly larger striatal lesions produced by both 3-NP and malonate. SOD2+/− mice also showed an increased production of “hydroxyl” radicals after malonate injection measured with the salicylate hydroxyl radical trapping method. These results provide further evidence that reactive oxygen species play an important role in the neurotoxicity of MPTP, malonate, and 3-NP. These findings show that a subclinical deficiency in a free radical scavenging enzyme may act in concert with environmental toxins to produce selective neurodegeneration.

Decreased pulmonary radiation resistance of manganese superoxide dismutase (MnSOD)-deficient mice is corrected by human manganese superoxide dismutase-Plasmid/Liposome (SOD2-PL) intratracheal gene therapy.

The pulmonary ionizing radiation sensitivity of C57BL/6 Sod2(+/-) mice heterozygous for MnSOD deficiency was compared to that Sod2(+/+) control littermates. Embryo fibroblast cell lines from Sod2(-/-) (neonatal lethal) or Sod2(+/-) mice produced less biochemically active MnSOD and demonstrated a significantly greater in vitro radiosensitivity. No G(2)/M-phase cell cycle arrest after 5 Gy was observed in Sod2(-/-) cells compared to the Sod2(+/-) or Sod2(+/+) lines. Subclonal Sod2(-/-) or Sod2(+/-) embryo fibroblast lines expressing the human SOD2 transgene showed increased biochemical activity of MnSOD and radioresistance. Sod2(+/-) mice receiving 18 Gy whole-lung irradiation died sooner and had an increased percentage of lung with organizing alveolitis between 100 and 160 days compared to Sod2(+/+) wild-type littermates. Both Sod2(+/-) and Sod2(+/+) littermates injected intratracheally with human manganese superoxide dismutase-plasmid/liposome (SOD2-PL) complex 24 h prior to whole-lung irradiation showed decreased DNA strand breaks and improved survival with decreased organizing alveolitis. Thus underexpression of MnSOD in the lungs of heterozygous Sod2(+/-) knockout mice is associated with increased pulmonary radiation sensitivity and parallels increased radiation sensitivity of embryo fibroblast cell lines in vitro. The restoration of cellular radioresistance in vitro and in lungs in vivo by SOD2-PL transgene expression supports a potential role for SOD2-PL gene therapy in organ-specific radioprotection.

Altered calcium homeostasis in spinal motoneurons but not in oculomotor neurons of SOD-1 knockout mice.

SOD-1-deficient mice demonstrate no loss of motoneurons but are still vulnerable to axotomy and ischemic insults. To investigate possible reasons for vulnerability of motoneuron populations, we studied changes in ultrastructural calcium distribution during maturation in spinal- and oculomotor neurons in SOD-1(-/-) mice. Between 3 and 11 months the cytoplasmic component of the intracellular calcium changed at a lower rate in spinal motoneurons and motor axon terminals in the interosseus muscle of SOD-1(-/-) animals compared to wild-type controls. No such dissimilarities were noted in the oculomotor system, or in mitochondrial calcium contents of either cell type. These data suggest that the lack of SOD-1 may be associated with vulnerability to insult by depletion of non-mitochondrial calcium stores selectively in motoneurons lacking parvalbumin and/or calbindin D28K.

Neurodegeneration, myocardial injury, and perinatal death in mitochondrial superoxide dismutase-deficient mice.

Manganese superoxide dismutase (SOD2) converts superoxide to oxygen plus hydrogen peroxide and serves as the primary defense against mitochondrial superoxide. Impaired SOD2 activity in humans has been associated with several chronic diseases, including ovarian cancer and type I diabetes, and SOD2 overexpression appears to suppress malignancy in cultured cells. We have produced a line of SOD2 knockout mice (SOD2m1BCM/SOD2m1BCM) that survive up to 3 weeks of age and exhibit several novel pathologic phenotypes including severe anemia, degeneration of neurons in the basal ganglia and brainstem, and progressive motor disturbances characterized by weakness, rapid fatigue, and circling behavior. In addition, SOD2m1BCM/SOD2m1BCM mice older than 7 days exhibit extensive mitochondrial injury within degenerating neurons and cardiac myocytes. Approximately 10% of SOD2m1BCM/SOD2m1BCM mice exhibit markedly enlarged and dilated hearts. These observations indicate that SOD2 deficiency causes increased susceptibility to oxidative mitochondrial injury in central nervous system neurons, cardiac myocytes, and other metabolically active tissues after postnatal exposure to ambient oxygen concentrations. Our SOD2-deficient mice differ from a recently described model in which homozygotes die within the first 5 days of life with severe cardiomyopathy and do not exhibit motor disturbances, central nervous system injury, or ultrastructural evidence of mitochondrial injury.