SOD1 is a 32 kDahomodimer which forms abeta barrel (β-barrel) and contains an intramolecular disulfide bond and a binuclear Cu/Zn site in each subunit. This Cu/Zn site holds the copper and a zinc ion and is responsible for catalyzing thedisproportionation ofsuperoxide tohydrogen peroxide anddioxygen.[8][9] The maturation process of this protein is complex and not fully understood, involving the selective binding of copper and zinc ions, formation of the intra-subunitdisulfide bond between Cys-57 and Cys-146, and dimerization of the two subunits. The copper chaperone for Sod1 (CCS) facilitates copper insertion and disulfide oxidation. Although SOD1 is synthesized in the cytosol and can mature there, the fraction of expressed but still immature SOD1 that is targeted to the mitochondria must be inserted into the intermembrane space. There, it forms the disulfide bond, though not metalation, required for its maturation.[9] The mature protein is highly stable,[10] but unstable when in its metal-free and disulfide-reduced forms.[8][9][10] This manifests in vitro, as the loss of metal ions results in increased SOD1 aggregation, and in disease models, where low metalation is observed for insoluble SOD1. Moreover, the surface-exposed reduced cysteines could participate in disulfidecrosslinking and, thus, aggregation.[8]
SOD1 binds copper and zinc ions and is one of three superoxide dismutases responsible for destroying freesuperoxide radicals in the body. The encodedisozyme is a solublecytoplasmic andmitochondrial intermembrane space protein, acting as a homodimer to convert naturally occurring, but harmful, superoxide radicals to molecular oxygen andhydrogen peroxide.[9][11] Hydrogen peroxide can then be broken down by another enzyme called catalase.
SOD1 has been postulated tolocalize to theouter mitochondrial membrane (OMM), where superoxide anions would be generated, or theintermembrane space. The exact mechanisms for its localization remains unknown, but its aggregation to the OMM has been attributed to its association with BCL-2. Wildtype SOD1 has demonstrated antiapoptotic properties in neural cultures, while mutant SOD1 has been observed to promote apoptosis in spinal cord mitochondria, but not inliver mitochondria, though it is equally expressed in both. Two models suggest SOD1 inhibits apoptosis by interacting withBCL-2 proteins or the mitochondria itself.[6]
Most notably, SOD1 is pivotal inreactive oxygen species (ROS) release during oxidative stress byischemia-reperfusion injury, specifically in themyocardium as part of aheart attack (also known asischemic heart disease). Ischemic heart disease, which results from anocclusion of one of the majorcoronary arteries, is currently still the leading cause ofmorbidity andmortality in western society.[12][13] During ischemia reperfusion, ROS release substantially contribute to the cell damage and death via a direct effect on the cell as well as via apoptotic signals. SOD1 is known to have a capacity to limit the detrimental effects of ROS. As such, SOD1 is important for its cardioprotective effects.[14] In addition, SOD1 has been implicated in cardioprotection against ischemia-reperfusion injury, such as duringischemic preconditioning of the heart.[15] Although a large burst of ROS is known to lead to cell damage, a moderate release of ROS from the mitochondria, which occurs during nonlethal short episodes of ischemia, can play a significant triggering role in the signal transduction pathways of ischemic preconditioning leading to reduction of cell damage. It even has been observed that during this release of ROS, SOD1 plays an important role hereby regulating apoptotic signaling and cell death.
Mutations (over 150 identified to date) in this gene have been linked tofamilial amyotrophic lateral sclerosis.[19][20][21] However, several pieces of evidence also show that wild-type SOD1, under conditions of cellular stress, is implicated in a significant fraction of sporadic ALS cases, which represent 90% of ALS patients.[22]The most frequent mutations areA4V (in the U.S.A.) andH46R (Japan). In Iceland onlySOD1-G93S has been found. The most studied ALS mouse model isG93A. Rare transcript variants have been reported for this gene.[11]
Virtually all known ALS-causing SOD1 mutations act in adominant fashion; a single mutant copy of the SOD1 gene is sufficient to cause the disease. The exact molecular mechanism (or mechanisms) by which SOD1 mutations cause disease are unknown. It appears to be some sort of toxic gain of function,[21] as many disease-associated SOD1 mutants (including G93A and A4V) retain enzymatic activity and Sod1 knockout mice do not develop ALS (although they do exhibit a strong age-dependent distal motor neuropathy).
A4V (alanine at codon 4 changed tovaline) is the most common ALS-causing mutation in the U.S. population, with approximately 50% of SOD1-ALS patients carrying the A4V mutation.[25][26][27] Approximately 10 percent of all U.S. familial ALS cases are caused by heterozygous A4V mutations in SOD1. The mutation is rarely if ever found outside the Americas.
It was recently estimated that the A4V mutation occurred 540 generations (~12,000 years) ago. The haplotype surrounding the mutation suggests that the A4V mutation arose in the Asian ancestors of Native Americans, who reached the Americas through theBering Strait.[28]
The A4V mutant belongs to the WT-like mutants. Patients with A4V mutations exhibit variable age of onset, but uniformly very rapid disease course, with average survival after onset of 1.4 years (versus 3–5 years with other dominant SOD1 mutations, and in some cases such as H46R, considerably longer). This survival is considerably shorter than non-mutant SOD1 linked ALS.
H46R (histidine at codon 46 changed toarginine) is the most common ALS-causing mutation in the Japanese population, with about 40% of Japanese SOD1-ALS patients carrying this mutation. H46R causes a profound loss of copper binding in the active site of SOD1, and as such, H46R is enzymatically inactive. The disease course of this mutation is extremely long, with the typical time from onset to death being over 15 years.[29] Mouse models with this mutation do not exhibit the classical mitochondrial vacuolation pathology seen in G93A and G37R ALS mice and unlike G93A mice, deficiency of the major mitochondrial antioxidant enzyme,SOD2, has no effect on their disease course.[29]
G93A (glycine 93 changed to alanine) is a comparatively rare mutation, but has been studied very intensely as it was the first mutation to be modeled in mice. G93A is a pseudo-WT mutation that leaves the enzyme activity intact.[27] Because of the ready availability of the G93A mouse fromJackson Laboratory, many studies of potential drug targets and toxicity mechanisms have been carried out in this model. At least one private research institute (ALS Therapy Development Institute) is conducting large-scale drug screens exclusively in this mouse model. Whether findings are specific for G93A or applicable to all ALS-causing SOD1 mutations is at present unknown. It has been argued that certain pathological features of the G93A mouse are due to overexpression artifacts, specifically those relating to mitochondrial vacuolation (the G93A mouse commonly used from Jackson Lab has over 20 copies of the human SOD1 gene).[30] At least one study has found that certain features of pathology are idiosyncratic to G93A and not extrapolatable to all ALS-causing mutations.[29] Further studies have shown that the pathogenesis of the G93A and H46R models are clearly distinct; some drugs and genetic interventions that are highly beneficial/detrimental in one model have either the opposite or no effect in the other.[31][32][33]
Down syndrome (DS) is usually caused by atriplication of chromosome 21.Oxidative stress is thought to be an important underlying factor in DS-related pathologies. The oxidative stress appears to be due to the triplication and increased expression of the SOD1 gene located in chromosome 21. Increased expression of SOD1 likely causes increased production ofhydrogen peroxide leading to increased cellular injury.
The levels of 8-OHdG in theDNA of persons with DS, measured insaliva, were found to be significantly higher than in control groups.[34] 8-OHdG levels were also increased in theleukocytes of persons with DS compared to controls.[35] These findings suggest that oxidative DNA damage may lead to some of the clinical features of DS.
^abcRosen DR, Siddique T, Patterson D, Figlewicz DA, Sapp P, Hentati A, et al. (March 1993). "Mutations in Cu/Zn superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis".Nature.362 (6415):59–62.Bibcode:1993Natur.362...59R.doi:10.1038/362059a0.PMID8446170.S2CID265436.
^Maslov LN, Naryzhnaia NV, Podoksenov I, Prokudina ES, Gorbunov AS, Zhang I, Peĭ Z (January 2015). "[Reactive oxygen species are triggers and mediators of an increase in cardiac tolerance to impact of ischemia-reperfusion]".Rossiiskii Fiziologicheskii Zhurnal imeni I.M. Sechenova.101 (1):3–24.PMID25868322.
^Liem DA, Honda HM, Zhang J, Woo D, Ping P (December 2007). "Past and present course of cardioprotection against ischemia-reperfusion injury".Journal of Applied Physiology.103 (6):2129–2136.doi:10.1152/japplphysiol.00383.2007.PMID17673563.S2CID24815784.
^Muller FL, Lustgarten MS, Jang Y, Richardson A, Van Remmen H (August 2007). "Trends in oxidative aging theories".Free Radical Biology & Medicine.43 (4):477–503.doi:10.1016/j.freeradbiomed.2007.03.034.PMID17640558.
^Gagliardi S, Cova E, Davin A, Guareschi S, Abel K, Alvisi E, et al. (August 2010). "SOD1 mRNA expression in sporadic amyotrophic lateral sclerosis".Neurobiology of Disease.39 (2):198–203.doi:10.1016/j.nbd.2010.04.008.PMID20399857.S2CID207065284.
^Kikuchi H, Furuta A, Nishioka K, Suzuki SO, Nakabeppu Y, Iwaki T (April 2002). "Impairment of mitochondrial DNA repair enzymes against accumulation of 8-oxo-guanine in the spinal motor neurons of amyotrophic lateral sclerosis".Acta Neuropathologica.103 (4):408–414.doi:10.1007/s00401-001-0480-x.PMID11904761.S2CID2102463.
^Warita H, Hayashi T, Murakami T, Manabe Y, Abe K (April 2001). "Oxidative damage to mitochondrial DNA in spinal motoneurons of transgenic ALS mice".Brain Research. Molecular Brain Research.89 (1–2):147–152.doi:10.1016/S0169-328X(01)00029-8.PMID11311985.
^Rosen DR, Bowling AC, Patterson D, Usdin TB, Sapp P, Mezey E, et al. (June 1994). "A frequent ala 4 to val superoxide dismutase-1 mutation is associated with a rapidly progressive familial amyotrophic lateral sclerosis".Human Molecular Genetics.3 (6):981–987.doi:10.1093/hmg/3.6.981.PMID7951249.
^Broom WJ, Johnson DV, Auwarter KE, Iafrate AJ, Russ C, Al-Chalabi A, et al. (January 2008). "SOD1A4V-mediated ALS: absence of a closely linked modifier gene and origination in Asia".Neuroscience Letters.430 (3):241–245.doi:10.1016/j.neulet.2007.11.004.PMID18055113.S2CID46282375.
^abcMuller FL, Liu Y, Jernigan A, Borchelt D, Richardson A, Van Remmen H (September 2008). "MnSOD deficiency has a differential effect on disease progression in two different ALS mutant mouse models".Muscle & Nerve.38 (3):1173–1183.doi:10.1002/mus.21049.PMID18720509.S2CID23971601.
^Bhattacharya A, Bokov A, Muller FL, Jernigan AL, Maslin K, Diaz V, et al. (August 2012). "Dietary restriction but not rapamycin extends disease onset and survival of the H46R/H48Q mouse model of ALS".Neurobiology of Aging.33 (8):1829–1832.doi:10.1016/j.neurobiolaging.2011.06.002.PMID21763036.S2CID11227242.
^Komatsu T, Duckyoung Y, Ito A, Kurosawa K, Maehata Y, Kubodera T, et al. (September 2013). "Increased oxidative stress biomarkers in the saliva of Down syndrome patients".Archives of Oral Biology.58 (9):1246–1250.doi:10.1016/j.archoralbio.2013.03.017.PMID23714170.
^Pallardó FV, Degan P, d'Ischia M, Kelly FJ, Zatterale A, Calzone R, et al. (August 2006). "Multiple evidence for an early age pro-oxidant state in Down Syndrome patients".Biogerontology.7 (4):211–220.doi:10.1007/s10522-006-9002-5.PMID16612664.S2CID13657691.
^Cova E, Ghiroldi A, Guareschi S, Mazzini G, Gagliardi S, Davin A, et al. (October 2010). "G93A SOD1 alters cell cycle in a cellular model of Amyotrophic Lateral Sclerosis".Cellular Signalling.22 (10):1477–1484.doi:10.1016/j.cellsig.2010.05.016.PMID20561900.
^Cereda C, Cova E, Di Poto C, Galli A, Mazzini G, Corato M, Ceroni M (November 2006). "Effect of nitric oxide on lymphocytes from sporadic amyotrophic lateral sclerosis patients: toxic or protective role?".Neurological Sciences.27 (5):312–316.doi:10.1007/s10072-006-0702-z.PMID17122939.S2CID25059353.
^Cova E, Cereda C, Galli A, Curti D, Finotti C, Di Poto C, et al. (May 2006). "Modified expression of Bcl-2 and SOD1 proteins in lymphocytes from sporadic ALS patients".Neuroscience Letters.399 (3):186–190.doi:10.1016/j.neulet.2006.01.057.PMID16495003.S2CID26076370.
Ceroni M, Curti D, Alimonti D (2002). "Amyotrophic lateral sclerosis and SOD1 gene: an overview".Functional Neurology.16 (4 Suppl):171–180.PMID11996514.
Zelko IN, Mariani TJ, Folz RJ (August 2002). "Superoxide dismutase multigene family: a comparison of the CuZn-SOD (SOD1), Mn-SOD (SOD2), and EC-SOD (SOD3) gene structures, evolution, and expression".Free Radical Biology & Medicine.33 (3):337–349.doi:10.1016/S0891-5849(02)00905-X.PMID12126755.
Hadano S (June 2002). "[Causative genes for familial amyotrophic lateral sclerosis]".Seikagaku. The Journal of Japanese Biochemical Society.74 (6):483–489.PMID12138710.
Noor R, Mittal S, Iqbal J (September 2002). "Superoxide dismutase--applications and relevance to human diseases".Medical Science Monitor.8 (9):RA210 –RA215.PMID12218958.
Potter SZ, Valentine JS (April 2003). "The perplexing role of copper-zinc superoxide dismutase in amyotrophic lateral sclerosis (Lou Gehrig's disease)".Journal of Biological Inorganic Chemistry.8 (4):373–380.doi:10.1007/s00775-003-0447-6.PMID12644909.S2CID22820101.
Jafari-Schluep HF, Khoris J, Mayeux-Portas V, Hand C, Rouleau G, Camu W (January 2004). "[Superoxyde dismutase 1 gene abnormalities in familial amyotrophic lateral sclerosis: phenotype/genotype correlations. The French experience and review of the literature]".Revue Neurologique.160 (1):44–50.doi:10.1016/S0035-3787(04)70846-2.PMID14978393.
Gagliardi S, Ogliari P, Davin A, Corato M, Cova E, Abel K, et al. (August 2011). "Flavin-containing monooxygenase mRNA levels are up-regulated in als brain areas in SOD1-mutant mice".Neurotoxicity Research.20 (2):150–158.doi:10.1007/s12640-010-9230-y.PMID21082301.S2CID21856030.
Battistini S, Ricci C, Lotti EM, Benigni M, Gagliardi S, Zucco R, et al. (June 2010). "Severe familial ALS with a novel exon 4 mutation (L106F) in the SOD1 gene".Journal of the Neurological Sciences.293 (1–2):112–115.doi:10.1016/j.jns.2010.03.009.PMID20385392.S2CID24895265.
![2nnx: Crystal Structure of the H46R, H48Q double mutant of human [Cu-Zn] Superoxide Dismutase](/mt/?noimg=&dark=on&url=http%3a%2f%2fen.wikipedia.org%2fwiki%2fFile%3aPDB_2nnx_EBI.png)