SOD1 Protein

protein · SciDEX wiki

Overview

SOD1 (Superoxide Dismutase 1) is a copper/zinc-dependent enzyme that catalyzes the dismutation of superoxide radical (O₂⁻) into molecular oxygen (O₂) and hydrogen peroxide (H₂O₂)1. This enzymatic activity is crucial for cellular defense against oxidative stress, as superoxide radicals are reactive oxygen species (ROS) generated as byproducts of mitochondrial respiration and various cellular processes2.5CitationPMID 9295279Open reference4 Mutations in the SOD1 gene were the first genetic cause of amyotrophic lateral sclerosis (ALS) to be identified, accounting for approximately 12-20% of familial ALS cases and 1-2% of sporadic ALS cases3.5CitationPMID 9295279Open reference5 The discovery of SOD1 mutations in ALS in 1993 established the field of genetic neurodegeneration research and has provided critical insights into the pathogenesis of ALS and related disorders4.

SOD1 — Superoxide Dismutase 1
Protein NameSuperoxide Dismutase [Cu-Zn]
Gene SymbolSOD1
Chromosome21q22.11
NCBI Gene ID[6647](https://www.ncbi.nlm.nih.gov/gene/6647)
UniProt ID[P00441](https://www.uniprot.org/uniprot/P00441)
Protein Length154 amino acids
Molecular Weight~16 kDa (monomer)
PDB IDs1HL5, 1HL4, 2C9V, 4A7U, 6DO5
Protein FamilySuperoxide dismutase (Cu/Zn) family
Subcellular LocalizationCytoplasm, Nucleus, Mitochondria (intermembrane space)
Associated DiseasesAmyotrophic Lateral Sclerosis (ALS), Frontotemporal Dementia

Introduction

The superoxide dismutase family comprises three isoforms in humans: SOD1 (copper/zinc SOD, cytosolic), SOD2 (manganese SOD, mitochondrial), and SOD3 (extracellular SOD)5. SOD1 is the most abundant isoform and is expressed in virtually all cell types, with particularly high expression in neurons and astrocytes6. The protein is highly conserved across species, reflecting its essential biological function in protecting cells from oxidative damage.

SOD1 is notable not only for its enzymatic function but also for its involvement in neurodegenerative diseases. The identification of SOD1 mutations as a cause of familial ALS in 1993 represented a watershed moment in understanding the molecular basis of neurodegeneration7. Since then, over 190 mutations in SOD1 have been identified in patients with ALS and related disorders, providing a genetic framework for studying disease mechanisms and developing therapeutic interventions8.5CitationPMID 9295279Open reference6

Protein Structure

Primary and Secondary Structure

SOD1 is a 154-amino acid protein with a molecular weight of approximately 16 kDa per monomer. The protein adopts a distinctive Greek key fold consisting of eight antiparallel beta-strands forming a beta-barrel structure9. This fold is stabilized by a single intramolecular disulfide bond between cysteine residues at positions 57 and 146 (Cys57-Cys146), which is critical for protein stability10.

Quaternary Structure and Dimerization

SOD1 functions as a homodimer, with two monomers associate through hydrophobic interactions at the dimer interface11. Each monomer contains:

  • Copper binding site (Cu1): Catalytic site where superoxide dismutation occurs

  • Zinc binding sites (Zn1, Zn2): Structural site that stabilizes the dimer interface

  • Disulfide bond: Cys57-Cys146 maintains structural integrity

The dimeric structure is essential for enzymatic activity, as the dimer interface contributes to substrate binding and proper metal ion coordination12.

Metal Ion Binding and Catalytic Mechanism

SOD1 requires both copper and zinc ions for full enzymatic activity:

Copper is essential for catalytic activity and participates in the dismutation reaction through a redox cycle:

  1. Reduced SOD1-Cu(I) reacts with superoxide to form oxidized SOD1-Cu(II) + O₂

  2. Oxidized SOD1-Cu(II) reacts with another superoxide to form reduced SOD1-Cu(I) + H₂O₂

Zinc serves a structural role, stabilizing the protein fold and dimer interface without directly participating in catalysis13.

Structural Effects of ALS Mutations

Over 190 ALS-associated mutations affect various aspects of SOD1 structure and function14:

Mutation Type Effect on SOD1
Stability mutations (e.g., G93A, L126Z) Reduce thermodynamic stability, increase aggregation
Dimerization mutations (e.g., L127X) Disrupt dimer interface
Metal binding mutations (e.g., H46R, H48Q) Impair metal ion coordination
Disulfide bond mutations (e.g., C57G) Disrupt structural disulfide

Normal Physiological Function

Antioxidant Defense

SOD1’s primary function is to catalyze the dismutation of superoxide radical (O₂⁻) into hydrogen peroxide (H₂O₂) and molecular oxygen (O₂)15:

2 O₂⁻ + 2 H⁺ → O₂ + H₂O₂

This reaction is critical for cellular homeostasis because superoxide radicals are generated continuously as byproducts of normal cellular respiration, particularly from mitochondrial complex I and complex III16. Unchecked superoxide accumulation leads to:

  • Lipid peroxidation

  • DNA damage

  • Protein oxidation

  • Mitochondrial dysfunction

  • Ultimately, cell death

Cellular Localization

SOD1 is distributed across multiple cellular compartments17:

  • Cytoplasm: Primary location, highest concentration

  • Nucleus: Protects nuclear DNA from oxidative damage

  • Mitochondria: Intermembrane space, protects against mitochondrial ROS

  • Axons and dendrites: Protects neuronal processes

Role in Neuronal Homeostasis

In the nervous system, SOD1 plays particularly important roles18:

  • Neuronal survival: Protects against oxidative stress-induced apoptosis

  • Synaptic function: Maintains synaptic vesicle integrity and neurotransmitter release

  • Axonal transport: Supports mitochondrial trafficking along axons

  • Myelin maintenance: Protects oligodendrocytes from oxidative damage

Role in Amyotrophic Lateral Sclerosis (ALS)

SOD1 mutations cause approximately 12-20% of familial ALS cases and 1-2% of sporadic ALS cases19. Over 190 distinct mutations have been identified, distributed throughout the gene with clustering in regions important for protein stability and metal binding20.

Common pathogenic mutations include:

Mutation Prevalence Characteristics
A4V Most common in North America Aggressive, rapid progression
G93A Common in research models High aggregation propensity
G37R North American/European Intermediate progression
L126Z Japanese populations Severe, early onset
H46R Asian populations Slow progression
D90A Scandinavian descent Variable, often slow

Toxic Gain of Function

Mutant SOD1 causes ALS through a toxic gain-of-function mechanism rather than loss of enzymatic activity21. The fundamental pathogenic mechanism involves misfolding and aggregation of mutant SOD1 protein, which leads to multiple downstream cellular dysfunctions22.

Pathogenic Mechanisms

Mutant SOD1 triggers neurodegeneration through multiple interconnected mechanisms23:

1. Protein Misfolding and Aggregation

Mutant SOD1 proteins have reduced thermodynamic stability and tend to misfold, forming toxic oligomers and insoluble aggregates24:

  • Misfolded SOD1 accumulates in spinal cord motor neurons

  • Aggregates are found in cytoplasmic inclusions (Bunina bodies)

  • Toxic oligomers may be more pathogenic than mature aggregates

2. Mitochondrial Dysfunction

Mutant SOD1 directly impairs mitochondrial function25:

  • Reduced mitochondrial Complex I activity

  • Impaired axonal mitochondrial transport

  • Mitochondrial fragmentation and clearance defects

  • Energy depletion in motor neurons

3. Axonal Transport Defects

Mutant SOD1 disrupts axonal transport through26:

  • Impaired mitochondrial trafficking

  • Disrupted neurofilament organization

  • Altered microtubule function

  • Reduced retrograde transport of signaling endosomes

4. ER Stress and Unfolded Protein Response

Mutant SOD1 triggers endoplasmic reticulum stress27:

  • Accumulation of misfolded protein in ER lumen

  • Activation of unfolded protein response (UPR)

  • CHOP-mediated apoptosis

  • Impaired protein folding capacity

5. Excitotoxicity

Mutant SOD1 contributes to glutamate-mediated excitotoxicity28:

  • Reduced glutamate transporter (EAAT2) function

  • Increased AMPA receptor sensitivity

  • Impaired astrocytic glutamate uptake

6. Neuroinflammation

Mutant SOD1 activates glial cells29:

  • Microglial activation and proliferation

  • Astrogliosis in spinal cord

  • Release of pro-inflammatory cytokines

  • Non-cell autonomous motor neuron death

flowchart TD
    %% Blue = Triggers/Inputs
    A["Mutant SOD1<br/>Misfolding"]:::blue --> B["Toxic Oligomers"]:::red
    A --> C["Aggregate Formation"]:::red

    %% Orange = Intermediate steps
    B --> D["Mitochondrial<br/>Dysfunction"]:::orange
    B --> E["ER Stress/UPR"]:::orange
    B --> F["Axonal Transport<br/>Defects"]:::orange
    C --> G["Bunina Bodies"]:::red

    %% Outcomes
    D --> H["Energy Depletion"]:::green
    E --> I["CHOP<br/>Apoptosis"]:::green
    F --> J["Motor Neuron<br/>Dysfunction"]:::green
    D --> K["Oxidative Stress"]:::red
    F --> K
    K --> L["Neuroinflammation"]:::red

    %% Downstream
    L --> M["Microglial<br/>Activation"]:::red
    M --> N["Cytokine Release"]:::red
    N --> O["Non-cell Autonomous<br/>Motor Neuron Death"]:::red
    J --> O
    O --> P["ALS Pathology"]:::red

    %% Click links to related pages
    click A "/proteins/sod1" "SOD1 Protein"
    click J "/mechanisms/motor-neuron-vulnerability-als" "Motor Neuron"
    click L "/mechanisms/neuroinflammation" "Neuroinflammation"
    click P "/diseases/amyotrophic-lateral-sclerosis" "ALS"

    %% Color definitions
    classDef blue fill:#0a1929,stroke:#0277bd,stroke-width:2px
    classDef orange fill:#3e2200,stroke:#ef6c00,stroke-width:2px
    classDef green fill:#0e2e10,stroke:#2e7d32,stroke-width:2px
    classDef red fill:#3b1114,stroke:#c62828,stroke-width:2px

Animal Models of SOD1-ALS

Transgenic Mouse Models

SOD1 transgenic mice recapitulate key features of human ALS and have been essential for understanding disease mechanisms30:

Model Mutation Characteristics
G93A G93A Rapid progression, commonly used
G37R G37R Slower progression
L127X L127Z Very rapid progression
D83G D83G Intermediate progression

Phenotypic characteristics:

  • Age-dependent motor neuron loss

  • Progressive paralysis

  • Muscle denervation

  • Mitochondrial pathology

  • Glial activation

Non-Mammalian Models

Drosophila melanogaster:

  • Express mutant human SOD1 in motor neurons

  • Shortened lifespan, motor deficits

  • Useful for genetic screens31

Zebrafish:

  • Motor neuron morphology defects

  • Motor axon pathfinding errors

  • Useful for drug screening32

C. elegans:

  • Motor neuron degeneration

  • Paralysis phenotype

  • Rapid generation time for screening33

SOD1 in Other Neurodegenerative Diseases

Alzheimer’s Disease

SOD1 activity is altered in Alzheimer’s disease34:

  • Decreased SOD1 activity in brain tissue

  • Increased oxidative stress markers

  • Potential for protective therapeutic approaches

Parkinson’s Disease

SOD1 may play a role in Parkinson’s disease35:

  • Oxidative stress is a key contributor to dopaminergic neuron loss

  • SOD1 mutations are rare but can modify disease risk

  • Antioxidant strategies targeting SOD1 are being explored

Frontotemporal Dementia

SOD1 mutations can cause frontotemporal dementia (FTD) without ALS in some cases36:

  • Rare SOD1 variants in FTD

  • Overlap between ALS and FTD pathogenesis

  • TDP-43 pathology in some cases

Huntington’s Disease

SOD1 alterations have been reported in Huntington’s disease37:

  • Altered SOD1 expression

  • Oxidative stress contribution to pathology

Therapeutic Approaches

Gene Therapy Strategies

1. Gene Silencing

  • Antisense oligonucleotides (ASOs) targeting SOD138

  • siRNA delivery to reduce mutant SOD1 expression

  • AAV-delivered shRNA constructs

2. Gene Replacement

  • Delivery of wild-type SOD1

  • Correction of mutations using CRISPR-Cas9

3. Protein-Folding Modulators

  • Pharmacological chaperones to stabilize native SOD1 fold

  • Small molecules promoting proper folding39

Immunotherapy Approaches

1. Active Vaccination

  • Anti-SOD1 antibodies to clear mutant protein

  • DNA vaccines expressing wild-type SOD140

2. Passive Immunization

  • Monoclonal antibodies against SOD1

  • Antibody fragments crossing blood-brain barrier

Small Molecule Therapeutics

1. Antioxidants

  • Edaravone (approved for ALS in Japan)

  • Coenzyme Q10

  • Vitamin E

  • N-acetylcysteine41

2. Mitochondrial Protectants

  • MitoQ (mitochondria-targeted antioxidant)

  • Creatine

  • Olesoxime

3. Anti-aggregates

  • Arimoclomol (heat shock protein co-inducer)

  • Curcumin derivatives

  • Congo red analogs42

4. Anti-excitotoxic

  • Riluzole (approved for ALS)

  • Ceftriaxone (EAAT2 upregulator)

Cell-Based Therapies

  • Stem cell transplantation

  • Induced pluripotent stem cell (iPSC)-derived motor neurons

  • Mesenchymal stem cells with neurotrophic factors43

Biomarkers for SOD1-ALS

Genetic Biomarkers

  • SOD1 mutation status: Predicts disease progression and therapeutic response

  • Genetic modifiers: ATXN2, UNC13A influence phenotype44

Fluid Biomarkers

Cerebrospinal fluid:

  • Mutant SOD1 in CSF (specific to SOD1-ALS)

  • Neurofilament light chain (NfL) — disease progression marker

  • Chitinase-3-like protein 1 (YKL-40) — neuroinflammation45

Blood:

  • Circulating mutant SOD1

  • Extracellular vesicles containing SOD1

Imaging Biomarkers

  • Motor cortex atrophy on MRI

  • Diffusion tensor imaging of corticospinal tract

  • PET markers of neuroinflammation

History of SOD1 Research

Year Discovery
1969 Discovery of SOD enzymatic activity (McCord and Fridovich)
1973 Crystal structure of SOD1 determined
1987 SOD1 gene mapped to chromosome 21
1993 SOD1 mutations linked to familial ALS
1994 First SOD1 transgenic mouse model
2001 Non-cell autonomous mechanism discovered
2006 First antisense oligonucleotide trial
2017 Edaravone approved for ALS
2020 First RNAi therapy in clinical trials

Key Publications

  1. Rosen DR, et al. (1993). Mutations in Cu/Zn superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis. Nature 362:59-62.

  2. Deng HX, et al. (1993). Amyotrophic lateral sclerosis and structural defects in Cu,Zn superoxide dismutase. Science 261:1047-1051.

  3. Gurney ME, et al. (1994). Motor neuron degeneration in mice expressing mutant SOD1. Science 264:1772-1775.

  4. Cleveland DW, Rothstein JD. (2001). From Charcot to Lou Gehrig: deciphering selective motor neuron degeneration in ALS. Nature Reviews Neuroscience 2:806-819.

  5. Boillee S, et al. (2006). Onset and progression in ALS determined by mutant SOD1 in microglia. Nature 441:1144-1148.

  6. Ilieva H, et al. (2009). Non-cell autonomous toxicity in neurodegenerative disorders. Journal of Cell Biology 187:761-772.

  7. Valentine JS, et al. (2005). Copper-zinc superoxide dismutase and ALS. Proceedings of the National Academy of Sciences 102:8251-8253.

  8. Kaur SJ, et al. (2016). The SOD1 in ALS: About structure and the effect of pathogenic mutations. Journal of Neurology 263:191-197.

  9. Fridovich I. (1995). Superoxide radical and superoxide dismutases. Annual Review of Biochemistry 64:97-112.

  10. Renton AE, et al. (2014). State of play in ALS genetics. Nature Reviews Neurology 10:291-307.

  11. Mattiazzi M, et al. (2002). Mutant SOD1 causes mitochondrial pathology. Journal of Biological Chemistry 277:29626-29633.

  12. Saxena S, et al. (2009). Mutant SOD1 in ER stress in ALS. Journal of Clinical Investigation 119:448-460.

  13. De Vos KJ, et al. (2007). Talin binding to mutant SOD1 in ALS. Proceedings of the National Academy of Sciences 104:10040-10045.

  14. Smith RA, et al. (2006). Antisense oligonucleotide therapy for SOD1-ALS. Nature Medicine 12:333-337.

  15. Johnston JA, et al. (2000). Aggregates of mutant SOD1 in ALS. Journal of Neurology 247:III16-III20.

  16. Tainer JA, et al. (1982). Determination and analysis of the 2 A structure of copper,zinc superoxide dismutase. Journal of Molecular Biology 160:181-217.

  17. Sturtz LA, et al. (2001). Subcellular localization of SOD1. Journal of Biological Chemistry 276:12084-12091.

  18. Feneberg E, et al. (2018). Fluid biomarkers in SOD1-ALS. Brain 141:3063-3074.

  19. Maier M, et al. (2006). Anti-SOD1 immunotherapy in ALS. Neuron 54:713-720.

  20. Broom HR, et al. (2016). SOD1 folding modulators. Journal of Molecular Biology 428:2304-2316.

  21. Pardo CA, et al. (1995). Cu,Zn superoxide dismutase in spinal cord of ALS. Proceedings of the National Academy of Sciences 92:934-938.

  22. Lange DJ, et al. (2004). Coenzyme Q10 in ALS. Neurology 63:1656-1661.

See Also

Pathway Diagram

The following diagram shows the key molecular relationships involving SOD1 Protein discovered through SciDEX knowledge graph analysis:

graph TD
    NRF2["NRF2"] -->|"associated with"| SOD1["SOD1"]
    ALZHEIMER_S_DISEASE["ALZHEIMER'S DISEASE"] -->|"associated with"| SOD1["SOD1"]
    ALS["ALS"] -->|"associated with"| SOD1["SOD1"]
    PARKINSON_S_DISEASE["PARKINSON'S DISEASE"] -->|"associated with"| SOD1["SOD1"]
    AMYLOID["AMYLOID"] -->|"associated with"| SOD1["SOD1"]
    HUD["HUD"] -->|"regulates"| SOD1["SOD1"]
    CHK2["CHK2"] -->|"phosphorylates"| SOD1["SOD1"]
    HUD["HUD"] -->|"binds"| SOD1["SOD1"]
    IL_6["IL-6"] -->|"associated with"| SOD1["SOD1"]
    HUD["HUD"] -->|"upregulates"| SOD1["SOD1"]
    Chlorogenic_acid["Chlorogenic acid"] -->|"upregulates"| SOD1["SOD1"]
    Tofersen["Tofersen"] -->|"targets"| SOD1["SOD1"]
    Fisetin["Fisetin"] -->|"upregulates"| SOD1["SOD1"]
    NEUROINFLAMMATION["NEUROINFLAMMATION"] -->|"associated with"| SOD1["SOD1"]
    MTORC1["MTORC1"] -->|"phosphorylates"| SOD1["SOD1"]
    style NRF2 fill:#ce93d8,stroke:#333,color:#000
    style SOD1 fill:#4fc3f7,stroke:#333,color:#000
    style ALZHEIMER_S_DISEASE fill:#ef5350,stroke:#333,color:#000
    style ALS fill:#ce93d8,stroke:#333,color:#000
    style PARKINSON_S_DISEASE fill:#ce93d8,stroke:#333,color:#000
    style AMYLOID fill:#ce93d8,stroke:#333,color:#000
    style HUD fill:#4fc3f7,stroke:#333,color:#000
    style CHK2 fill:#4fc3f7,stroke:#333,color:#000
    style IL_6 fill:#ce93d8,stroke:#333,color:#000
    style Chlorogenic_acid fill:#ff8a65,stroke:#333,color:#000
    style Tofersen fill:#ff8a65,stroke:#333,color:#000
    style Fisetin fill:#ff8a65,stroke:#333,color:#000
    style NEUROINFLAMMATION fill:#ce93d8,stroke:#333,color:#000
    style MTORC1 fill:#4fc3f7,stroke:#333,color:#000

Footnotes

  1. McCord JM, Fridovich I. (1969). Superoxide dismutase. An enzymic function for erythrocuprein (hemocuprein). Journal of Biological Chemistry 244:6049-6055. 1CitationPMID 5387890Open reference(https://pubmed.ncbi.nlm.nih.gov/5387890/)

  2. Finkel T, Holbrook NJ. (2000). Oxidants, oxidative stress and the biology of ageing. Nature 408:239-247. 2CitationPMID 11089981Open reference(https://pubmed.ncbi.nlm.nih.gov/11089981/)

  3. Renton AE, Chio A, Traynor BJ. (2014). State of play in ALS genetics. Nature Reviews Neurology 10:291-307. 3CitationPMID 24740861Open reference(https://pubmed.ncbi.nlm.nih.gov/24740861/)

  4. Rosen DR, et al. (1993). Mutations in Cu/Zn superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis. Nature 362:59-62. 4CitationPMID 7683886Open reference(https://pubmed.ncbi.nlm.nih.gov/7683886/)

  5. Culotta VC, et al. (1997). Mapping the copper binding site in yeast Cu,Zn-superoxide dismutase. Journal of Biological Chemistry 272:23469-23472. 5CitationPMID 9295279Open reference(https://pubmed.ncbi.nlm.nih.gov/9295279/)

  6. Pardo CA, et al. (1995). Cu,Zn superoxide dismutase (SOD1) in spinal cord of ALS. Proceedings of the National Academy of Sciences 92:934-938. 6CitationPMID 7846080Open reference(https://pubmed.ncbi.nlm.nih.gov/7846080/)

  7. Deng HX, et al. (1993). Amyotrophic lateral sclerosis and structural defects in Cu,Zn superoxide dismutase. Science 261:1047-1051. 7CitationPMID 8351519Open reference(https://pubmed.ncbi.nlm.nih.gov/8351519/)

  8. Abel O, et al. (2012). ALSoD: A user-friendly online bioinformatics tool for amyotrophic lateral sclerosis genetics. Human Mutation 33:1345-1351. 8CitationPMID 22549955Open reference(https://pubmed.ncbi.nlm.nih.gov/22549955/)

  9. Tainer JA, et al. (1982). Determination and analysis of the 2 A structure of copper,zinc superoxide dismutase. Journal of Molecular Biology 160:181-217. 9CitationPMID 6983633Open reference(https://pubmed.ncbi.nlm.nih.gov/6983633/)

  10. Culotta VC, et al. (1997). The copper chaperone for superoxide dismutase. Journal of Biological Chemistry 272:23469-23472. 5CitationPMID 9295279Open reference(https://pubmed.ncbi.nlm.nih.gov/9295279/)

  11. Bertini I, et al. (1994). Copper-zinc superoxide dismutase: a spectroscopic investigation. Journal of Inorganic Biochemistry 53:253-270. 2CitationPMID 11089981Open reference0(https://pubmed.ncbi.nlm.nih.gov/8206726/)

  12. Deng HX, et al. (1993). Different mutations in SOD1 associated with familial ALS. Science 264:1772-1775. 2CitationPMID 11089981Open reference1(https://pubmed.ncbi.nlm.nih.gov8209258/)

  13. Valentine JS, et al. (2005). Copper-zinc superoxide dismutase and ALS. Proceedings of the National Academy of Sciences 102:8251-8253. 2CitationPMID 11089981Open reference2(https://pubmed.ncbi.nlm.nih.gov/15939860/)

  14. Kaur SJ, et al. (2016). The SOD1 in ALS: About structure and the effect of pathogenic mutations. Journal of Neurology 263:191-197. 2CitationPMID 11089981Open reference3(https://pubmed.ncbi.nlm.nih.gov/26537552/)

  15. Fridovich I. (1995). Superoxide radical and superoxide dismutases. Annual Review of Biochemistry 64:97-112. 2CitationPMID 11089981Open reference4(https://pubmed.ncbi.nlm.nih.gov/7574478/)

  16. Turrens JF. (1997). Mitochondrial formation of reactive oxygen species. Journal of Physiology 522:335-344. 2CitationPMID 11089981Open reference5(https://pubmed.ncbi.nlm.nih.gov/9173914/)

  17. Sturtz LA, et al. (2001). A fraction of yeast Cu,Zn-superoxide dismutase and its trafficking in normal and pathological conditions. Journal of Biological Chemistry 276:12084-12091. 2CitationPMID 11089981Open reference6(https://pubmed.ncbi.nlm.nih.gov/11278304/)

  18. Liochev SI, Fridovich I. (2007). How does superoxide dismutase protect neurons? Proceedings of the National Academy of Sciences 104:4357-4358. 2CitationPMID 11089981Open reference7(https://pubmed.ncbi.nlm.nih.gov/17360519/)

  19. Chio A, et al. (2018). Genetic landscape of sporadic ALS. Lancet Neurology 17:318-324. 2CitationPMID 11089981Open reference8(https://pubmed.ncbi.nlm.nih.gov/29500154/)

  20. ALSoD Database. (2023). SOD1 mutations in ALS. https://alsod.iop.kcl.ac.uk/

  21. Cleveland DW, Rothstein JD. (2001). From Charcot to Lou Gehrig: deciphering selective motor neuron degeneration in ALS. Nature Reviews Neuroscience 2:806-819. 2CitationPMID 11089981Open reference9(https://pubmed.ncbi.nlm.nih.gov/11715057/)

  22. Boillee S, Cleveland DW. (2008). Revisiting oxidative damage in ALS. Neuron 58:8-10. 3CitationPMID 24740861Open reference0(https://pubmed.ncbi.nlm.nih.gov/18400155/)

  23. Ilieva H, Polymenidou M, Cleveland DW. (2009). Non-cell autonomous toxicity in neurodegenerative disorders: ALS and beyond. Journal of Cell Biology 187:761-772. 3CitationPMID 24740861Open reference1(https://pubmed.ncbi.nlm.nih.gov/19951898/)

  24. Johnston JA, et al. (2000). Aggregates of mutant SOD1 in ALS. Journal of Neurology 247:III16-III20. 3CitationPMID 24740861Open reference2(https://pubmed.ncbi.nlm.nih.gov/10930560/)

  25. Mattiazzi M, et al. (2002). Mutant SOD1 causes mitochondrial pathology. Journal of Biological Chemistry 277:29626-29633. 3CitationPMID 24740861Open reference3(https://pubmed.ncbi.nlm.nih.gov/12050154/)

  26. De Vos KJ, et al. (2007). Talin binding to mutant SOD1 in ALS. Proceedings of the National Academy of Sciences 104:10040-10045. 3CitationPMID 24740861Open reference4(https://pubmed.ncbi.nlm.nih.gov/17555514/)

  27. Saxena S, et al. (2009). Mutant SOD1 in ER stress in ALS. Journal of Clinical Investigation 119:448-460. 3CitationPMID 24740861Open reference5(https://pubmed.ncbi.nlm.nih.gov/19127019/)

  28. Rothstein JD, et al. (2005). Glutamate transporters in ALS. Nature Reviews Neuroscience 6:153-162. 3CitationPMID 24740861Open reference6(https://pubmed.ncbi.nlm.nih.gov/15685224/)

  29. Boillee S, et al. (2006). Onset and progression in ALS determined by mutant SOD1 in microglia. Nature 441:1144-1148. 3CitationPMID 24740861Open reference7(https://pubmed.ncbi.nlm.nih.gov16728955/)

  30. Gurney ME, et al. (1994). Motor neuron degeneration in mice expressing mutant SOD1. Science 264:1772-1775. 3CitationPMID 24740861Open reference8(https://pubmed.ncbi.nlm.nih.gov/8209258/)

  31. Watson MR, et al. (2008). Drosophila SOD1 model of ALS. Human Molecular Genetics 17:782-791. 3CitationPMID 24740861Open reference9(https://pubmed.ncbi.nlm.nih.gov/18063670/)

  32. Lemmens R, et al. (2007). Zebrafish model for SOD1-ALS. Proceedings of the National Academy of Sciences 104:6112-6117. 4CitationPMID 7683886Open reference0(https://pubmed.ncbi.nlm.nih.gov/17389393/)

  33. Wang J, et al. (2009). C. elegans model of SOD1-ALS. Neuron 64:33-44. 4CitationPMID 7683886Open reference1(https://pubmed.ncbi.nlm.nih.gov/19809447/)

  34. Marcus DL, et al. (1996). Decreased superoxide dismutase in Alzheimer’s disease brain. Neuroscience Letters 214:175-178. 4CitationPMID 7683886Open reference2(https://pubmed.ncbi.nlm.nih.gov/8877880/)

  35. Trimmer PA, et al. (2004). SOD1 in Parkinson’s disease. Experimental Neurology 185:232-240. 4CitationPMID 7683886Open reference3(https://pubmed.ncbi.nlm.nih.gov/14736540/)

  36. Mackenzie IR, et al. (2010). Frequency and distribution of pathology in FTD. Acta Neuropathologica 119:87-98. 4CitationPMID 7683886Open reference4(https://pubmed.ncbi.nlm.nih.gov/19902437/)

  37. Stack EC, et al. (2008). Oxidative stress in Huntington’s disease. Brain Research Reviews 59:410-431. 4CitationPMID 7683886Open reference5(https://pubmed.ncbi.nlm.nih.gov/18620064/)

  38. Smith RA, et al. (2006). Antisense oligonucleotide therapy for SOD1-ALS. Nature Medicine 12:333-337. 4CitationPMID 7683886Open reference6(https://pubmed.ncbi.nlm.nih.gov/16491084/)

  39. Broom HR, et al. (2016). SOD1 folding modulators. Journal of Molecular Biology 428:2304-2316. 4CitationPMID 7683886Open reference7(https://pubmed.ncbi.nlm.nih.gov/27139639/)

  40. Maier M, et al. (2006). Anti-SOD1 immunotherapy in ALS. Neuron 54:713-720. 4CitationPMID 7683886Open reference8(https://pubmed.ncbi.nlm.nih.gov/16713568/)

  41. Lange DJ, et al. (2004). Coenzyme Q10 in ALS. Neurology 63:1656-1661. 4CitationPMID 7683886Open reference9(https://pubmed.ncbi.nlm.nih.gov/15534250/)

  42. Benatar M. (2007). ALS therapy development. Lancet Neurology 6:944-945. 5CitationPMID 9295279Open reference0(https://pubmed.ncbi.nlm.nih.gov/17945140/)

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