GSTP1 Polymorphisms and their Association with Glutathione Transferase and Peroxidase Activities in Patients with Motor Neuron Disease.

Glutathione S-transferase pi (GSTP1) is a crucial enzyme in detoxification of electrophilic compounds and organic peroxides. Together with Se-dependent glutathione peroxidase (Se-GSHPx) it protects cells against oxidative stress which may be a primary factor implicated in motor neuron disease (MND) pathogenesis. We investigated GSTP1 polymorphisms and their relationship with GST and Se-GSTPx activities in a cohort of Polish patients with MND. Results were correlated with clinical phenotypes. The frequency of genetic variants for GSTP1 exon 5 (I105V) and exon 6 (A114V) was studied in 104 patients and 100 healthy controls using real-time polymerase chain reaction. GST transferase activity was determined in serum with 1-chloro-2,4-dinitrobenzene, its peroxidase activity with cumene hydroperoxide, and Se-GSHPx activity with hydrogen peroxide. There were no differences in the prevalence of GSTP1 polymorphism I105V and A114V between MND and controls, however the occurrence of CT variant in codon 114 was associated with a higher risk for MND. GSTP1 polymorphisms were less frequent in classic ALS than in progressive bulbar palsy. In classic ALS C* (heterozygous I /V and A /V) all studied activities were significantly lower than in classic ALS A* (homozygous I /I and A/A). GST peroxidase activity and Se-GSHPx activity were lower in classic ALS C* than in control C*, but in classic ALS A* Se-GSHPx activity was significantly higher than in control A*. It can be concluded that the presence of GSTP1 A114V but not I105V variant increases the risk of MND, and combined GSTP1 polymorphisms in codon 105 and 114 may result in lower protection of MND patients against the toxicity of electrophilic compounds, organic and inorganic hydroperoxides.

Histone acetylation as a potential therapeutic target in motor neuron degenerative diseases.

Among hereditary diseases, the group of motor neuron diseases (MNDs) includes some of the most devastating and rapidly progressive lethal conditions. Although degeneration of motor neurons is common to all of them, the phenotypic spectrum of MNDs is relatively broad and ranges from perinatal conditions like spinal muscular atrophy (SMA) to adult-onset diseases such as amyotrophic lateral sclerosis (ALS). While the understanding of the pathology of the diseases is constantly growing, the development of therapeutic approaches lags behind. In fact, there is no approved therapy for MNDs available at the moment. Recent findings demonstrated the existence of some patterns that are shared by several MNDs such as transcriptional dysregulation. In addition, conditions like SMA or certain types of Charcot-Marie-Tooth disease provide some defined targets which may be amenable to therapeutic approaches. Consequently, counteracting this dysregulation may be a valuable therapeutic option and ameliorate disease progression in MND patients. The feasibility of such an approach has been proven during the past years by the epigenetic treatment of various neoplastic entities with histone deacetylase inhibitors (HDACi). On these grounds, also epigenetic therapy of MNDs has become a promising option. So far, several HDACi have been tested in vitro and in animal models and some proceeded further and were evaluated in clinical trials. This review will summarize the advances of HDACi in MNDs and will give a perspective where the road will lead us.

Neuropathy target esterase (NTE): overview and future.

Neuropathy target esterase (NTE) was discovered by M.K. Johnson in his quest for the entity responsible for the striking and mysterious paralysis brought about by certain organophosphorus (OP) esters. His pioneering work on OP neuropathy led to the view that the biochemical lesion consisted of NTE that had undergone OP inhibition and aging. Indeed, nonaging NTE inhibitors failed to produce disease but protected against neuropathy from subsequently administered aging inhibitors. Thus, inhibition of NTE activity was not the culprit; rather, formation of an abnormal protein was the agent of the disorder. More recently, however, Paul Glynn and colleagues showed that whereas conventional knockout of the NTE gene was embryonic lethal, conditional knockout of central nervous system NTE produced neurodegeneration, suggesting to these authors that the absence of NTE rather than its presence in some altered form caused disease. We now know that NTE is the 6th member of a 9-protein family called patatin-like phospholipase domain-containing proteins, PNPLA1-9. Mutations in the catalytic domain of NTE (PNPLA6) are associated with a slowly developing disease akin to OP neuropathy and hereditary spastic paraplegia called NTE-related motor neuron disorder (NTE-MND). Furthermore, the NTE protein from affected individuals has altered enzymological characteristics. Moreover, closely related PNPLA7 is regulated by insulin and glucose. These seemingly disparate findings are not necessarily mutually exclusive, but we need to reconcile recent genetic findings with the historical body of toxicological data indicating that inhibition and aging of NTE are both necessary in order to produce neuropathy from exposure to certain OP compounds. Solving this mystery will be satisfying in itself, but it is also an enterprise likely to pay dividends by enhancing our understanding of the physiological and pathogenic roles of the PNPLA family of proteins in neurological health and disease, including a potential role for NTE in diabetic neuropathy.

Reduced activity of AMP-activated protein kinase protects against genetic models of motor neuron disease.

A growing body of research indicates that amyotrophic lateral sclerosis (ALS) patients and mouse models of ALS exhibit metabolic dysfunction. A subpopulation of ALS patients possesses higher levels of resting energy expenditure and lower fat-free mass compared to healthy controls. Similarly, two mutant copper zinc superoxide dismutase 1 (mSOD1) mouse models of familial ALS possess a hypermetabolic phenotype. The pathophysiological relevance of the bioenergetic defects observed in ALS remains largely elusive. AMP-activated protein kinase (AMPK) is a key sensor of cellular energy status and thus might be activated in various models of ALS. Here, we report that AMPK activity is increased in spinal cord cultures expressing mSOD1, as well as in spinal cord lysates from mSOD1 mice. Reducing AMPK activity either pharmacologically or genetically prevents mSOD1-induced motor neuron death in vitro. To investigate the role of AMPK in vivo, we used Caenorhabditis elegans models of motor neuron disease. C. elegans engineered to express human mSOD1 (G85R) in neurons develops locomotor dysfunction and severe fecundity defects when compared to transgenic worms expressing human wild-type SOD1. Genetic reduction of aak-2, the ortholog of the AMPK α2 catalytic subunit in nematodes, improved locomotor behavior and fecundity in G85R animals. Similar observations were made with nematodes engineered to express mutant tat-activating regulatory (TAR) DNA-binding protein of 43 kDa molecular weight. Altogether, these data suggest that bioenergetic abnormalities are likely to be pathophysiologically relevant to motor neuron disease.

The in vivo contribution of motor neuron TrkB receptors to mutant SOD1 motor neuron disease.

Brain-derived neurotrophic factor (BDNF) and its receptor tropomyosin-related kinase B (TrkB) are widely expressed in the vertebrate nervous system and play a central role in mature neuronal function. In vitro BDNF/TrkB signaling promotes neuronal survival and can help neurons resist toxic insults. Paradoxically, BDNF/TrkB signaling has also been shown, under certain in vitro circumstances, to render neurons vulnerable to insults. We show here that in vivo conditional deletion of TrkB from mature motor neurons attenuates mutant superoxide dismutase 1 (SOD1) toxicity. Mutant SOD1 mice lacking motor neuron TrkB live a month longer than controls and retain motor function for a longer period, particularly in the early phase of the disease. These effects are subserved by slowed motor neuron loss, persistence of neuromuscular junction integrity and reduced astrocytic and microglial reactivity within the spinal cord. These results suggest that manipulation of BDNF/TrkB signaling might have therapeutic efficacy in motor neuron diseases.

Sporadic motor neuron disease in a familial novel SOD1 mutation: incomplete penetrance or chance association?

Cu/Zn superoxide dismutase (SOD1) gene mutations have been reported in familial and sporadic amyotrophic lateral sclerosis (ALS). We report a novel G61R SOD1 mutation in a patient with a distinct phenotype including prominent lower motor neuron dysfunction, proximal weakness and atrophy with asymmetrical onset in the thigh and buttock and relentless clinical course. The G61R mutation segregated in three unaffected relatives including the 80-year-old mother and two of the proband's siblings. Potential mechanisms include an autosomal dominant condition with reduced penetrance or a chance association.

Motor neuron disease due to neuropathy target esterase gene mutation: clinical features of the index families.

Recently, we reported that mutations in the neuropathy target esterase (NTE) gene cause autosomal recessive motor neuron disease (NTE-MND). We describe clinical, neurophysiologic, and neuroimaging features of affected subjects in the index families. NTE-MND subjects exhibited progressive lower extremity spastic weakness that began in childhood and was later associated with atrophy of distal leg and intrinsic hand muscles. NTE-MND resembles Troyer syndrome, except that short stature, cognitive impairment, and dysmorphic features, which often accompany Troyer syndrome, are not features of NTE-MND. Early onset, symmetry, and slow progression distinguish NTE-MND from typical amyotrophic lateral sclerosis. NTE is implicated in organophosphorus compound-induced delayed neurotoxicity (OPIDN). NTE-MND patients have upper and lower motor neuron deficits that are similar to OPIDN. Motor neuron degeneration in subjects with NTE mutations supports the role of NTE and its biochemical cascade in the molecular pathogenesis of OPIDN and possibly other degenerative neurologic disorders.

Motor neuron disease due to neuropathy target esterase mutation: enzyme analysis of fibroblasts from human subjects yields insights into pathogenesis.

Recently, we identified neuropathy target esterase (NTE) mutation as the cause of an autosomal recessive motor neuron disease (NTE-MND). Subsequently, we showed that NTE-MND mutations reduced specific activity (SA) and altered inhibitory kinetics of NTE catalytic domain constructs. Recent preliminary results showed that NTE is expressed in cultured human skin fibroblasts, and others have used mutant forms of neuronal proteins expressed in fibroblasts as biomarkers of neurogenetic diseases. Therefore, the present study was carried out to test the hypothesis that NTE in cultured skin fibroblasts from NTE-MND subjects also exhibit altered enzymological properties assessed by SA and IC(50) values of mipafox (MIP) and chlorpyrifos oxon (CPO). NTE SA was reduced to 65% of control (wild-type NTE from commercially obtained fibroblasts) in homozygous M1012V fibroblasts and 59-61% of control in compound heterozygous R890H/c2946_2947InsCAGC fibroblasts. MIP IC(50) values were unaffected by the NTE mutations, but the CPO IC(50) increased 4.5-fold in homozygous M1012V fibroblasts. Interestingly, markedly reduced NTE SAs (40-43% of control) were observed in fibroblasts from asymptomatic subjects heterozygous for NTE insertion c2946_2947InsCAGC. This insertion is predicted to produce truncated NTE missing the last 235 residues of its catalytic domain. These observations confirm that NTE-MND mutations reduce NTE SA in vitro. Moreover, to the extent observations made in cultured fibroblasts may be generalized to events in the nervous system, lack of correlation between reduced fibroblast NTE SA and the occurrence of NTE-MND in NTE insertion mutation heterozygotes indicates that reduction of NTE SA alone is insufficient to cause MND.

Wild-type human SOD1 overexpression does not accelerate motor neuron disease in mice expressing murine Sod1 G86R.

Approximately 10% of the cases of amyotrophic lateral sclerosis (ALS) are inherited, with the majority of identified linkages in the gene encoding Cu/Zn superoxide dismutase (SOD1). Recent studies showed that human wild-type SOD1 (SOD1(WT)) overexpression accelerated disease in mice expressing human SOD1 mutants linked to ALS. However, there is a controversy whether the exacerbation mechanism occurs through coaggregation of human SOD1(WT) with SOD1 mutants, stabilization by SOD1(WT) of toxic soluble SOD1 species, or conversion of SOD1(WT) into toxic species through oxidative damage. To further address whether the exacerbation of disease requires misfolding, modifications, and/or interaction of SOD1(WT) with pathogenic forms of SOD1 species, we have studied the effect of human SOD1(WT) overexpression in mice expressing the murine mutant Sod1(G86R). Surprisingly, unlike a previous report with SOD1(G85R) mice, SOD1(WT) overexpression did not affect the life span of Sod1(G86R) mice. Our analysis of spinal cord extracts revealed a lack of heterodimerization or aggregation between human SOD1(WT) and mouse Sod1(G86R) proteins. Moreover, there was no evidence of conversion of SOD1(WT) into misfolded or abnormal SOD1 isoforms based on immunoreactivity with monoclonal antibodies specific to misfolded forms of SOD1 mutants and on analysis of SOD1 isoforms after two-dimensional gel electrophoresis. We conclude that a direct interaction between wild type and mutant forms of SOD1 is required for exacerbation of ALS disease by SOD1(WT) protein.

Constructs of human neuropathy target esterase catalytic domain containing mutations related to motor neuron disease have altered enzymatic properties.

Neuropathy target esterase (NTE) is a phospholipase/lysophospholipase associated with organophosphorus (OP) compound-induced delayed neurotoxicity (OPIDN). Distal degeneration of motor axons occurs in both OPIDN and the hereditary spastic paraplegias (HSPs). Recently, mutations within the esterase domain of NTE were identified in patients with a novel type of HSP (SPG39) designated NTE-related motor neuron disease (NTE-MND). Two of these mutations, arginine 890 to histidine (R890H) and methionine 1012 to valine (M1012V), were created in human recombinant NTE catalytic domain (NEST) to measure possible changes in catalytic properties. These mutated enzymes had decreased specific activities for hydrolysis of the artificial substrate, phenyl valerate. In addition, the M1012V mutant exhibited a reduced bimolecular rate constant of inhibition (k(i)) for all three inhibitors tested: mipafox, diisopropylphosphorofluoridate, and chlorpyrifos oxon. Finally, while both mutated enzymes inhibited by OP compounds exhibited altered time-dependent loss of their ability to be reactivated by nucleophiles (aging), more pronounced effects were seen with the M1012V mutant. Taken together, the results from specific activity, inhibition, and aging experiments suggest that the mutations found in association with NTE-MND have functional correlates in altered enzymological properties of NTE.

Familial amyotrophic lateral sclerosis with a novel G85S mutation of superoxide dismutase 1 gene: clinical features of lower motor neuron disease.

Amyotrophic lateral sclerosis (ALS) is a devastating disease characterized by upper and lower motor neuron damage. Mutations of Cu/Zn superoxide dismutase gene (SOD1) account for 20% of familial ALS (FALS). We report a unique clinicogenotype of a Japanese family with a novel SOD 1 mutation. A 37-year-old woman (the proband) noticed muscle weakness in the left lower limb. Her mother had developed progressive lower motor neuron signs in four extremities at 38 years of age. Subsequently she was diagnosed as ALS and died of respiratory failure at 15 months after clinical onset. Neurological examination of the proband showed absent muscle stretch reflexes in the left knee and the left ankle without Babinski signs. Mild to moderate degree of muscle weakness existed in the left lower extremity. Muscle atrophy was presented in the left thigh. Initial pulmonary function revealed forced vital capacity of 91.1%. Electromyography disclosed ongoing denervation muscle potentials in the left lower extremity. SOD1 analysis demonstrated amino acid substitution of glycine by serine at codon 85 (G85S) in exon 4. Six months later, marked muscle weakness and atrophy expanded to four extremities. All muscle stretch reflexes were absent. Three months later, ventilator support with a tracheostomy was needed. The patient died at 18 months after clinical onset. Clinical hallmarks of this FALS family indicate that G85S mutation of SOD1 may cause rapidly progressive form of pure lower motor neuron signs.

Mutant glycyl-tRNA synthetase (Gars) ameliorates SOD1(G93A) motor neuron degeneration phenotype but has little affect on Loa dynein heavy chain mutant mice.

BACKGROUND: In humans, mutations in the enzyme glycyl-tRNA synthetase (GARS) cause motor and sensory axon loss in the peripheral nervous system, and clinical phenotypes ranging from Charcot-Marie-Tooth neuropathy to a severe infantile form of spinal muscular atrophy. GARS is ubiquitously expressed and may have functions in addition to its canonical role in protein synthesis through catalyzing the addition of glycine to cognate tRNAs. METHODOLOGY/PRINCIPAL FINDINGS: We have recently described a new mouse model with a point mutation in the Gars gene resulting in a cysteine to arginine change at residue 201. Heterozygous Gars(C201R/+) mice have locomotor and sensory deficits. In an investigation of genetic mutations that lead to death of motor and sensory neurons, we have crossed the Gars(C201R/+) mice to two other mutants: the TgSOD1(G93A) model of human amyotrophic lateral sclerosis and the Legs at odd angles mouse (Dync1h1(Loa)) which has a defect in the heavy chain of the dynein complex. We found the Dync1h1(Loa/+);Gars(C201R/+) double heterozygous mice are more impaired than either parent, and this is may be an additive effect of both mutations. Surprisingly, the Gars(C201R) mutation significantly delayed disease onset in the SOD1(G93A);Gars(C201R/+) double heterozygous mutant mice and increased lifespan by 29% on the genetic background investigated. CONCLUSIONS/SIGNIFICANCE: These findings raise intriguing possibilities for the study of pathogenetic mechanisms in all three mouse mutant strains.

Interaction of amyotrophic lateral sclerosis (ALS)-related mutant copper-zinc superoxide dismutase with the dynein-dynactin complex contributes to inclusion formation.

An important consequence of protein misfolding related to neurodegenerative diseases, including amyotrophic lateral sclerosis (ALS), is the formation of proteinaceous inclusions or aggregates within the central nervous system. We have previously shown that several familial ALS-linked copper-zinc superoxide dismutase (SOD1) mutants (A4V, G85R, and G93A) interact and co-localize with the dynein-dynactin complex in cultured cells and affected tissues of ALS mice. In this study, we report that the interaction between mutant SOD1 and the dynein motor plays a critical role in the formation of large inclusions containing mutant SOD1. Disruption of the motor by overexpression of the p50 subunit of dynactin in neuronal and non-neuronal cell cultures abolished the association between aggregation-prone SOD1 mutants and the dynein-dynactin complex. The p50 overexpression also prevented mutant SOD1 inclusion formation and improved the survival of cells expressing A4V SOD1. Furthermore, we observed that two ALS-linked SOD1 mutants, H46R and H48Q, which showed a lower propensity to interact with the dynein motor, also produced less aggregation and fewer large inclusions. Overall, these data suggest that formation of large inclusions depends upon association of the abnormal SOD1s with the dynein motor. Whether the misfolded SOD1s directly perturb axonal transport or impair other functional properties of the dynein motor, this interaction could propagate a toxic effect that ultimately causes motor neuron death in ALS.

The endoplasmic reticulum-Golgi pathway is a target for translocation and aggregation of mutant superoxide dismutase linked to ALS.

Mutations in superoxide dismutase 1 (SOD1) are responsible for 20% cases of familial amyotrophic lateral sclerosis (ALS). However, the mechanism of motor neuron degeneration caused by ALS-linked SOD1 mutants is not fully understood. Here, we used novel live cell imaging techniques to demonstrate the subcellular localization of EGFP-fused SOD1 of both wild-type (WT) and ALS-linked mutant forms in the endoplasmic reticulum (ER) and Golgi. The presence of WT and mutant SOD1 species in luminal structures was further confirmed by immunoblotting analysis of microsomal fractions from spinal cord lysates of SOD1 transgenic mice prepared by sucrose density-gradient ultracentrifugation. Chemical cross-linking studies also revealed an age-dependent aggregation of mutant SOD1, but not of WT SOD1, prominently in the microsomal fraction. Cell-free translocation assays provided evidence that monomeric SOD1 is a molecular form that can be translocated into luminal structures in the presence of ATP. Our finding that the ER-Golgi pathway is a predominant cellular site of aggregation of mutant SOD1 suggests that secretion could play a key role in pathogenesis, which is in line with the view that the disease is non-cell autonomous.

The rare G93D mutation causes a slowly progressing lower motor neuron disease.

We describe an ALS family with the rare SOD1 G93D mutation. Three members of the family developed ALS at an age ranging from 45 to 71 years. In all cases pyramidal signs were not evident. Two members of the family were obligate gene carriers, and died at 56 and 81years, respectively, without developing ALS signs or symptoms. The mutation was found in the DNA extracted from the hair bulbs in the two deceased obligate carriers and in another family member who died at 80 years of age without any sign of the disease. This study shows that SOD1 G93D mutation causes a slowly developing lower motor neuron disease with a reduced penetrance.

Non-hydrolytic functions of acetylcholinesterase. The significance of C-terminal peptides.

This review explores the possibility that acetylcholinesterase may play a pivotal, non-hydrolytic role in neurodegeneration. More specifically, C-terminal sequences of acetylcholinesterase may act as signalling molecules in key brain regions characteristically vulnerable to Alzheimer's, Parkinson's and motor neuron disease.

Cysteine 111 affects aggregation and cytotoxicity of mutant Cu,Zn-superoxide dismutase associated with familial amyotrophic lateral sclerosis.

Converging evidence indicates that aberrant aggregation of mutant Cu,Zn-superoxide dismutase (mutSOD1) is strongly implicated in familial amyotrophic lateral sclerosis (FALS). MutSOD1 forms high molecular weight oligomers, which disappear under reducing conditions, both in neural tissues of FALS transgenic mice and in transfected cultured cells, indicating a role for aberrant intermolecular disulfide cross-linking in the oligomerization and aggregation process. To study the contribution of specific cysteines in the mechanism of aggregation, we mutated human SOD1 in each of its four cysteine residues and, using a cell transfection assay, analyzed the solubility and aggregation of those SOD1s. Our results suggest that the formation of mutSOD1 aggregates are the consequence of covalent disulfide cross-linking and non-covalent interactions. In particular, we found that the removal of Cys-111 strongly reduces the ability of a range of different FALS-associated mutSOD1s to form aggregates and impair cell viability in cultured NSC-34 cells. Moreover, the removal of Cys-111 impairs the ability of mutSOD1s to form disulfide cross-linking. Treatments that deplete the cellular pool of GSH exacerbate mutSOD1s insolubility, whereas an overload of intracellular GSH or overexpression of glutaredoxin-1, which specifically catalyzes the reduction of protein-SSG-mixed disulfides, significantly rescues mutSOD1s solubility. These data are consistent with the view that the redox environment influences the oligomerization/aggregation pathway of mutSOD1 and point to Cys-111 as a key mediator of this process.

Soluble misfolded subfractions of mutant superoxide dismutase-1s are enriched in spinal cords throughout life in murine ALS models.

Mutants of superoxide dismutase-1 (SOD1) cause ALS by an unidentified cytotoxic mechanism. We have previously shown that the stable SOD1 mutants D90A and G93A are abundant and show the highest levels in liver and kidney in transgenic murine ALS models, whereas the unstable G85R and G127X mutants are scarce but enriched in the CNS. These data indicated that minute amounts of misfolded SOD1 enriched in the motor areas might exert the ALS-causing cytotoxicity. A hydrophobic interaction chromatography (HIC) protocol was developed with the aim to determine the abundance of soluble misfolded SOD1 in tissues in vivo. Most G85R and G127X mutant SOD1s bound in the assay, but only minute subfractions of the D90A and G93A mutants. The absolute levels of HIC-binding SOD1 were, however, similar and broadly inversely related to lifespans in the models. They were generally enriched in the susceptible spinal cord. The HIC-binding SOD1 was composed of disulfide-reduced subunits lacking metal ions and also subunits that apparently carried nonnative intrasubunit disulfide bonds. The levels were high from birth until death and were comparable to the amounts of SOD1 that become sequestered in aggregates in the terminal stage. The HIC-binding SOD1 species ranged from monomeric to trimeric in size. These species form a least common denominator amongst SOD1 mutants with widely different molecular characteristics and might be involved in the cytotoxicity that causes ALS.

Overexpression of mutant superoxide dismutase 1 causes a motor axonopathy in the zebrafish.

The development of small animal models is of major interest to unravel the pathogenesis and treatment of neurodegenerative diseases, especially because of their potential in large-scale chemical and genetic screening. We have investigated the zebrafish as a model to study amyotrophic lateral sclerosis (ALS), a fatal neurodegenerative disorder characterized by the selective loss of motor neurons, caused by mutations in superoxide dismutase 1 (SOD1) in a subset of patients. Overexpression of mutant human SOD1 in zebrafish embryos induced a motor axonopathy that was specific, dose-dependent and found for all mutations studied. Moreover, using this newly established animal model for ALS, we investigated the role of a known modifier in the disease: vascular endothelial growth factor (VEGF). Lowering VEGF induced a more severe phenotype, whereas upregulating VEGF rescued the mutant SOD1 axonopathy. This novel zebrafish model underscores the potential of VEGF for the treatment of ALS and furthermore will permit large-scale genetic and chemical screening to facilitate the identification of new therapeutic targets in motor neuron disease.