High Fructose Negatively Impacts Proliferation of NSC-34 Motor Neuron Cell Line.

Objectives The main aim of this study is to identify the deleterious effects of indiscriminately consumed high fructose on motor neurons that are critically affected in many neurological conditions causing movement disorders including paralysis. Materials and Methods Neuroblastoma x mouse spinal cord motor neuron cell line (NSC-34) motor neuron cell lines were treated with high fructose and oxygen supplementation (18.8%) and assayed for cell proliferation/death, reactive oxygen species (ROS) generation, and oxidative stress response induction Statistical Analysis Mean and standard deviation, significance with and without high fructose (F)-5%, were estimated by t -tests using GraphPad Prism ver. 8.2.1 Results F-5% along with O 2 (18.8%) annihilates the cells (∼85%) by day10 and inhibits cell division as observed by the presence of multinucleated cells. Unexpectedly, 1 to 2% of cells that survived, differentiated and displayed progressive neurite extension. Though not healthy, they were viable up to 80 days. F-5% increased ROS levels (∼34%) not accompanied by concomitant enhanced expression of oxidative stress response regulator, the transcription factor, nrf-2 , or downstream effector, sod-1. Conclusion High fructose is extremely harmful to NSC-34 motor neuron cell line.

Detrimental effects of fructose on mitochondria in mouse motor neurons and on C. elegans healthspan.

BACKGROUND: Fructose-common sweetener, consumed in large quantities, is now known to be associated with various metabolic diseases. Recent reports suggest fructose's involvement in neurodegeneration, neurotoxicity, and neuroinflammation. But, its impact at cellular and subcellular level and on energy metabolism, especially, mitochondrial bioenergetics, in neurons is not known. OBJECTIVES: To study the adverse effects of high fructose in general, and on the mitochondria in a spinal cord motor neuron cell line, NSC-34, in vitro, and Caenorhabditis elegans in vivo. METHODS: NSC-34 was treated with 0.5%-5% of fructose for different time periods. Fructose's effect on cell viability (MTT assay), metabolic activity (XF24 Seahorse assays) and C. elegans, chronically fed with 5% fructose and alteration in healthspan/mitochondria was monitored. RESULTS: In NSC-34: Fructose at 4-5% elicits 60% cell death. Unlike 1%, 5% fructose (F5%) decreased mitochondrial membrane potential by 29%. Shockingly, 6hours F5% treatment almost abolished mitochondrial respiration - basal-respiration (∨123%), maximal-respiration (∨ 95%) and spare-respiratory-capacity (∨ 83%) and ATP production (∨98%) as revealed by XF 24- Seahorse assays. But non - mitochondrial respiration was spared. F5% treatment for 48hrs resulted in the total shutdown of respiratory machinery including glycolysis. Chronic feeding of wildtype C.elegans to F5% throughout, shortened lifespan by ~3 days (∨ 17%), progressively reduced movement (day-2 -∨10.25%, day-5 -∨25% and day-10 -∨56%) and food intake with age (day-5-∨9% and day-10 -∨48%) and instigated mitochondrial swelling and disarray in their arrangement in adult worms body-wall muscle cells. CONCLUSION: Chronic exposure to high fructose negatively impacts cell viability, mitochondrial function, basal glycolysis, and healthspan.

DMSO Delays Alzheimer Disease Causing Aß-induced Paralysis in C. elegans Through Modulation of Glutamate/Acetylcholine Neurotransmission.

BACKGROUND: Alzheimer's disease (AD), a prevalent neurodegenerative disease with progressive dementia and neurotransmission (NT)-dysfunction-related complications in older adults, is known to be caused by abnormal Amyloid-ß (Aß) peptide and associated amyloid plaques in the brain. Drugs to cure AD are not in sight. Two major excitatory neurotransmitters, glutamate (Glu) and acetylcholine (ACh), and their signaling systems are implicated in AD. OBJECTIVE: To determine the effect of various NT-altering compounds including fenobam, quisqualic acid, and dimethyl sulfoxide (DMSO) in the protection against Aß toxicity. Further, to identify the potential mechanism through which the protection happens. METHODS: The well-known C. elegans AD model, CL4176, in which human Aß expression is turned on upon a temperature shift to 25 °C that leads to paralysis, was screened for protection/delay in paralysis because of Αß toxicity. While screening the compounds, dimethyl sulfoxide (DMSO), a universal solvent used to solubilize compounds, was identified to provide protection. Aldicarb and levamisole assays were performed to identify the contribution of ACh neurotransmission in Αß toxicity protection by DMSO. RESULTS: One percent and two percent DMSO delayed paralysis by 48% and 90%, respectively. DMSO was dominant over one of the Glu-NT pathway-related compounds, Fenobam-Group I mGluR antagonist. But DMSO provided only 30% to 50% protection against Quisqualic acid, the Glu-agonist. DMSO (2%) delayed ACh-NT, both presynaptic acetylcholine esterase inhibitor (AchEi)-aldicarb and postsynaptic-iAChR-agonst-levamisole induced paralysis, by ∼70% in CL4176. DMSO seems to be altering Ca2+ ion permeability essential for NT as EthyleneDiamine Tetra-Acetic acid (EDTA) and DMSO provided similar aldicarb resistance either combined or alone in wildtype worms. But postsynaptic Ca2+ depletion by EDTA could reverse DMSO-induced levamisole hypersensitivity. Surprisingly, the absence of FOrkhead boXO (FOXO) transcription factor homolog, daf-16 (loss-of-function mutant), a critical transcription factor in the reduced IIS-mediated longevity in C. elegans, abolished DMSO-mediated AldR. CONCLUSION: DMSO and Fenobam protect against Aß toxicity through modulation of NT.

Absence of metabotropic glutamate receptor homolog(s) accelerates acetylcholine neurotransmission in Caenorhabditis elegans.

Glutamate (Glu) and Acetylcholine (ACh), are excitatory neurotransmitters, acting through ionotropic (iR) and metabotropic receptors (mR). Importantly, both neurotransmitters and their signalling are impaired in the prevalent neurodegenerative disease-Alzheimer disease (AD). Glu and its signalling cascade's influence on ACh-neurotransmission (NT) are sparsely understood. The mGluRs coupled to G-protein signalling acting through PI3K cascade (GrpI) or inhibition of adenylate cyclase-cAMP cascade (GrpII and GrpIII) brings about long-lasting structural/functional changes. These complexities are challenging to decipher. Here, we report that human/mouse mGluRs when compared with their Caenorhabditis elegans homologs, MGL-1-3 showed overall of homology of ∼31-39 %. Phylogeneitc analysis revealed homology of MGL-2 to GrpI, MGL-3 with Grp1 &II and GRM6 of GrpIII and MGL-1, a low homology that falls between GrpI & GrpII. Then, alteration of ACh-NT in C. elegans loss-of-function mutants of mgl-1, mgl-2, mgl-3, PI3K (age-1) and iGluR (NMDA)(nmr-1) was estimated by well-established acute aldicarb (Ald), that increases ACh at synapse, and levamisole (Lev) (postsynaptic activation of levamisole sensitive iAChR) induced time-dependent paralysis assays. Surprisingly, all of them were hypersensitive to Ald and Lev compared to wildtype (in percentage), namely, mgl-1 -17, 54; mgl-2 - 7.2, 24; mgl-3 -52, 64; age-1 - 27, 32; nmr-1- 24, 48; respectively. Of the three, mgl-3 contributes to maximal overall acceleration of ACh-NT. Adenylate cyclase, acy-1 gain-of-function mutant showed less hypersensitivity, Ald - 7% and Lev- 25 %. Together, Glu receptors and signalling cascades are altering ACh-NT permanently, thus establishing the interplay between them thereby provide potential drug targets to be considered for AD.

Organic solvents can influence acetylcholine neurotransmission in Caenorhabditis elegans.

BACKGROUND: Identification of novel drugs by bio-prospecting natural products like various parts of the plants, or other extracts and drug discovery requires differential fractionation with various organic solvents followed by their concentration through evaporation under nitrogen gas, which is a standard practice. PURPOSE: Determination of contribution of vehicle control of organic solvents (chloroform, ethanol, ethyl acetate and n-hexane) processed in the similar manner in the modulation of acetylcholine(ACh) neurotransmission in Caenorhabditis elegans, Aldicarb induced paralysis assay. METHODS: The organic solvents concentrated as described in background was used to identify their contribution in ACh modulation through ACh esterase inhibitor, Aldicarb, treatment of C. elegans, which leads to time dependent paralysis of the worms. RESULTS: The vehicle, organic solvents, control itself bestows modulation of acetylcholine release as Aldicarb resistance in C. elegans. CONCLUSION: Given the exorbitant cost and time taken for drug discovery, identification of efficacy of bioactive molecules fractionated through organic solvents and concentrated under nitrogen gas should have appropriate vehicle control as described above to avoid the rate of false positives. This is universally applicable whether the drug is chemically synthesized or purified from natural products.

Reserpine requires the D2-type receptor, dop-3, and the exoribonuclease, eri-1, to extend the lifespan in C. elegans.

Lifespan extension is an all systems encompassing event. Involvement of reduced insulin/IGF1 signalling is well worked out, first in the model organism Caenorhbaditis elegans followed by other systems including humans. But the role of neuronal component in lifespan extension is not well understood due to the refractory nature of neurons to small RNA interference (sRNAi) in C. elegans. Earlier, we have demonstrated that an antihypertensive drug, reserpine, extends lifespan through modulation of neurotransmitter release, especially, acetylcholine, in C. elegans. Intriguingly, the reserpine mediated lifespan extension (RMLE) does not happen through the known longevity pathways. Here, we report that the D2-type dopamine receptor (DOP-3), which acts through the inhibitory Gprotein coupled (G alpha i) pathway mediated signalling is partly required for RMLE. In the dop-3 loss of function mutant RMLE is shortened. DOP-3 acts through Gαo (goa-1). One of the downstream targets of G protein signalling is the transcription factor, jun-1. MRP-1, an ATP binding cassette transporter, belonging to the multidrug resistance protein family is one of the genes turned on by JUN-1. RMLE is shortened in dop-3-->goa-1-->jun1-->mrp-1 loss of function mutants, elucidating the contribution of dop-3 signalling. The dop-3 receptor system is known to inhibit acetylcholine release. This suggests dopamine receptor, dop-3 could be contributing to the modulation of acetylcholine release by reserpine. ERI-1 is a 3'-5' exoribonuclease, one of the negative regulators of sRNAi, whose loss of function makes neurons amenable to siRNA. In the absence of eri-1, RMLE is shortened. In the dop-3 loss-of-function background, lack of eri-1 completely abolishes RMLE. This suggests that dop-3 and eri-1 act in independent parallel pathways for RMLE and these two pathways are essential and sufficient for the longevity enhancement by reserpine in C. elegans.

A Novel Way of Amelioration of Amyloid Beta Induced Toxicity in Caenorhabditis elegans.

BACKGROUND: With an incidence of 1 in 85 persons above the age of 60 years succumbing to the disease, Alzheimer's disease (AD), has been predicted to create havoc globally. In spite of enormous efforts and exhaustive research, no cure is in sight. Hence, it is critical to unravel the mechanism of AD development/protection and identification of a cure soon. PURPOSE: This study is aimed at investigating the mechanism of reserpine action, which alleviates the toxicity of amyloid beta (Aß) (AD-causing peptide) in Caenorhabditis elegans [1, 2]. METHODS: Determination of alleviation of Aß toxicity with reserpine manifested as reduction in progressive paralysis, in the background of GFP reporter driven by the promoter of the FMRFamide neuropeptide, FLP-11 (AD; Pflp-11::GFP) and acetylcholine contribution through aldicarb (which inhibits acetylcholine esterase) treatment. RESULTS: The most significant protection against Aß toxicity was obtained in the background of Pflp-11::GFP. This protection had 2 components. The promoter of FLP-11 with the reporter GFP, Pflp-11::GFP, per se gave significant protection. Further reserpine treatment provided additional alleviation. Together they could almost eliminate Aß toxicity. These 2 components of Aß toxicity alleviation are dependent on acetylcholine levels, as an increase in acetylcholine by aldicarb treatment reduces the protective effect. CONCLUSION: A unique way to alleviate Aß toxicity is reserpine treatment in combination with Pflp-11::GFP. Reserpine should be evaluated as a potential drug in a pilot study in AD patients. Furthermore, identification of the mechanism of Pflp-11::GFP-mediated reduction in Aß toxicity is a potential pathway to develop therapeutics for AD.

Secreted trophic factors of Human umbilical cord stromal cells induce differentiation and neurite extension through PI3K and independent of cAMP pathway.

BACKGROUND: Trophic factors (TFs) play important role during development and adult tissue maintenance. In neurodegenerative diseases (ND) TF supplementation provides protection. Stromal cells (HUMS) derived from the human umbilical cord matrix provide neuroprotection in the ND models of mice. PURPOSE: Though TF mediated protection is known, the exact mechanism of protection is not clear. So, here the essential TFs (secreted by HUMS cells) and the pathway of induction of neurite extension, differentiation and networking is addressed. METHODS: The HUMS cells from the human umbilical cord matrix were derived and the mouse spinal cord motor neuron cell line, NSC-34 was extensively used. Flow cytometry, immunohistochemistry, RT- PCR, western blot, ELISA and antibody/inhibitor treatment were carried out to figure out the TF pathway. RESULTS: The HUMS cells secrete six neurotrophic factors (sTFs), namely, NT-3, NGF, BDNF, VEGF, IGF-1 and GDNF (TFs). These TFs are sufficient to induce differentiation, neurite extension and neural networking in a motor neuron cell line, NSC34. All the 5 TFs need to be neutralized simultaneously with their antibodies to abrogate neurite extension. These motor neurons express the concomitant receptors, which are either receptor tyrosine kinase (TrK) coupled or to the receptor followed by the TrKs, for the above trophic factors (except for BDNF). The tyrosine kinase inhibitor, K252a, drastically reduces neurite extension. In NSC34, the TFs are coupled to the PI3K-Akt-pathway and the RAS-MAP kinase signaling through phosphorylation of ERK1 and ERK2. PI3K inhibitor, Ly 294002, abolishes neural differentiation and neurite extension. Thus, differentiation, neurite extension and networking could be achieved through the PI3K pathway. Intriguingly, the cAMP second messenger system coupling was not required. H89, PKA-inhibitor caused extensive cell death. But, had no effect in the presence of HUMS-secreted-TFs(HSTFs) suggesting a pathway switch for cell survival itself. CONCLUSION: HUMS cells and their secreted factors could be of great use in regenerative medicine (RM). The activators of PI3K pathway, the major route of these HUMS-TFs action could be explored in RM and in the neurobiology of neural differentiation and extension.

Withania somnifera root extract extends lifespan of Caenorhabditis elegans.

BACKGROUND: In the ancient Indian herbal medicine system several ayurvedic preparations are claimed to have longevity enhancing effects. But, so far, no clear scientific evidence has been provided. One among them, is the roots of the plant, commonly known as Ashwagandha (Withania somnifera Dunal- WSD), which is supposed to have myriad of beneficial effects including long life. PURPOSE: Here, we evaluated both the root extract (RE) and its purified ingredients (PI-RE) with a similar composition as in RE obtained from the roots of WSD for lifespan extension in the well established model system, C. elegans. PI-RE could extend the lifespan of C. elegans. METHODS: We used wild type C. elegans (N2) or RB918: acr-16 (ok789); andNL2099: rrf-3 (pk1426) mutant worms and analysed their lifespan assay in Ashwagandha extract spreaded on plates containing Bacterial Lawns. RESULTS: Strangely, while there was no effect on the wild type worms, the mutant for the human nicotinic acetylcholine receptor, nAchR, α7 equivalent, acr-16, showed around ~20% lifespan extension when treated with PI-RE. CONCLUSION: Thus, we are able to show that one of the age old healthy longlife supplements, Ashwagandha does extend lifespan of C. elegans.

Reserpine modulates neurotransmitter release to extend lifespan and alleviate age-dependent Aß proteotoxicity in Caenorhabditis elegans.

Aging is a debilitating process often associated with chronic diseases such as diabetes, cardiovascular and neurodegenerative diseases like Alzheimer's disease (AD). AD occurs at a very high incidence posing a huge burden to the society. Model organisms such as C. elegans become essential to understand aging or lifespan extension - the etiology, molecular mechanism and identification of new drugs against age associated diseases. The AD model, manifesting Aß proteotoxicity, in C. elegans is well established and has provided valuable insights. Earlier, we have reported that Reserpine, an FDA-approved antihypertensive drug, increases C. elegans lifespan with a high quality of life and ameliorates Aß toxicity in C. elegans. But reserpine does not seem to act through the known lifespan extension pathways or inhibition of its known target, vesicular monoamine transporter, VMAT. Reserpine's mode of action and the pathways it activates are not known. Here, we have evaluated the presynaptic neurotransmitter(s) release pathway and identified acetylcholine (ACh) as the crucial player for reserpine's action. The corroborating evidences are: i) lack of lifespan extension in the ACh loss of function (hypomorphic) - synthesis (cha-1) and transport (unc-17) mutants; ii) mitigation of chronic aldicarb effect; iii) lifespan extension in dopamine (cat-2) and dopamine and serotonin (bas-1) biosynthetic mutants; iv) no rescue from exogenous serotonin induced paralysis in the AD model worms; upon reserpine treatment. Thus, modulation of acetylcholine is essential for reserpine's action.

ALS associated mutant SOD1 impairs the motor neurons and astrocytes and wild type astrocyte secreted-factors reverse the impaired motor neurons.

BACKGROUND: Amyotrophic Lateral Sclerosis, in which motor neurons degenerate, leading to paralysis, not only the affected motor neurons, but the surrounding non-neuronal cells also contribute significantly to the disease. However, the disease mechanism is not known. PURPOSE: In this study we have addressed the disease mechanism by expressing the ALS associated mutant SOD1(G37R) in the motor neurons (mMN) and astrocytes (mA) cell lines. METHODS: A series of cell culture assays, immunostaining, RT-PCR and Western blot analysis were performed. RESULTS: We noticed impairments in both these cell types. The mMN motor neurons were insensitive to forskolin, a known activator of adenylate cyclase, which leads to motor neuron death. In addition, less number of mMN were positive for phosphorylated neurofilament-H (pNFH) unlike the normal motor neurons. Similarly, the mutant SOD1 expressing astrocytes (mA) had two impairments: The inability to activate the oxidative stress protection and the absence of secretory factor(s). Normal astrocytes and their secreted factors could restore the pNFH in the mMN but not the mA. In addition, we show that pNFH restoration is a specific function since the insensitivity of mMN to forskolin could be rescued by neither normal astrocytes nor their secreted factors. CONCLUSION: Thus we demonstrate some of the abnormalities caused by the ALS associated mutant SOD1(G37R) and a potential way, to reverse an abnormality through cell replacement.

Cerebrospinal fluid from sporadic amyotrophic lateral sclerosis patients induces degeneration of a cultured motor neuron cell line.

We investigated the effect of Cerebrospinal Fluid (CSF) from sporadic Amyotrophic Lateral Sclerosis patients (SALS-CSF) on motor neuron-like cells to delineate the pathomechanism of SALS. Exposure of NSC-34 cells to SALS-CSF caused lower viability, reduction in differentiation and enhanced lactate dehydrogenase activity. Additionally, reduced choline acetyl transferase expression alongside intracellular aggregation of phosphorylated neurofilaments was prominently seen. The aggregates were immunopositive for ubiquitin. These findings are comparable to the pathological changes seen in the postmortem tissue of ALS patients. Unlimited supply of NSC-34 cells and their vulnerability to SALS-CSF render them to be a good bioassay system to identify new therapeutic agents conferring protection to motor neurons.

Reserpine ameliorates Abeta toxicity in the Alzheimer's disease model in Caenorhabditis elegans.

Earlier we have reported that reserpine, an antihypertensive drug, known to downregulate biogenic amines through inhibition of the vesicular monoamine transporter (VMAT), increases longevity of Caenorhabditis elegans with a high quality of life, namely, enhanced and prolonged mobility (Srivastava et al., 2008). As neurodegenerative diseases are of adult onset, we addressed the protective ability of reserpine against neurodegenerative diseases, especially Alzheimer's disease (AD). In the well established AD model in C. elegans, Amyloid beta (Abeta) is expressed in the muscles and Abeta toxicity is manifested as paralysis (Link, 1995). In this model, reserpine significantly delayed paralysis and increased the longevity. In addition, reserpine provided thermotolerance, but interestingly the Abeta transcript and expression levels remains grossly unchanged.

Development and evaluation of an in vivo assay in Caenorhabditis elegans for screening of compounds for their effect on cytochrome P450 expression.

Most drugs and xenobiotics induce the expression of cytochrome P450 (CYP) enzymes, which reduce the bioavailability of the inducer and/or co-administered drugs. Therefore, evaluation of new drug candidates for their effect on CYP expression is an essential step in drug development. The available methods for this purpose are expensive and not amenable to high-throughput screening. We developed a fluorescence-based in vivo assay using transgenic Caenorhabditis elegans worms that express the green fluorescent protein (GFP) under the control of various CYP promoters. Using this assay, we found striking similarities between the worm CYPs and their human orthologs in their response to treatment with various drugs. For example,the antibiotic rifampicin, one of the strongest inducers of the human gene CYP3A4, was the strongest inducer of the worm ortholog CYP13A7. Since worms can be easily grown in liquid medium in microtitre plates, the assay described in this paper is suitable for the screening of a large number of potential lead compounds in the drug discovery process.

Reserpine can confer stress tolerance and lifespan extension in the nematode C. elegans.

Though the lifespan extension mechanism is partly understood from C. elegans to mice, a viable pharmacological intervention is not yet feasible. Here, we report that reserpine largely known as an antipsychotic-antihypertensive drug, can extend C. elegans lifespan. Chronic reserpine treatment from embryo stage or young adults extends the C. elegans lifespan robustly at 25 degrees C. Most importantly, the reserpine treated long lived worms are active (locomotion and pharyngeal pumping) for a long time thereby conferring high quality throughout life. Reserpine mediated lifespan extension is independent of the daf-16 pathway and partly requires serotonin. Reserpine treatment makes the worms highly thermotolerant. Thus, in addition to its known function, reserpine is able to provide stress tolerance and lifespan extension in C. elegans.

Toxicity of familial ALS-linked SOD1 mutants from selective recruitment to spinal mitochondria.

One cause of amyotrophic lateral sclerosis (ALS) is mutation in ubiquitously expressed copper/zinc superoxide dismutase (SOD1), but the mechanism of toxicity to motor neurons is unknown. Multiple disease-causing mutants, but not wild-type SOD1, are now demonstrated to be recruited to mitochondria, but only in affected tissues. This is independent of the copper chaperone for SOD1 and dismutase activity. Highly preferential association with spinal cord mitochondria is seen in human ALS for a mutant SOD1 that accumulates only to trace cytoplasmic levels. Despite variable proportions that are successfully imported, nearly constant amounts of SOD1 mutants and covalently damaged adducts of them accumulate as apparent import intermediates and/or are tightly aggregated or crosslinked onto integral membrane components on the cytoplasmic face of those mitochondria. These findings implicate damage from action of spinal cord-specific factors that recruit mutant SOD1 to spinal mitochondria as the basis for their selective toxicity in ALS.

Mechanisms for activating Cu- and Zn-containing superoxide dismutase in the absence of the CCS Cu chaperone.

The Cu- and Zn-containing superoxide dismutase 1 (SOD1) largely obtains Cu in vivo by means of the action of the Cu chaperone CCS. Yet, in the case of mammalian SOD1, a secondary pathway of activation is apparent. Specifically, when human SOD1 is expressed in either yeast or mammalian cells that are null for CCS, the SOD1 enzyme retains a certain degree of activity. This CCS-independent activity is evident with both wild-type and mutant variants of SOD1 that have been associated with familial amyotrophic lateral sclerosis. We demonstrate here that the CCS-independent activation of mammalian SOD1 involves glutathione, particularly the reduced form, or GSH. A role for glutathione in CCS-independent activation was seen with human SOD1 molecules that were expressed in either yeast cells or immortalized fibroblasts. Compared with mammalian SOD1, the Saccharomyces cerevisiae enzyme cannot obtain Cu without CCS in vivo, and this total dependence on CCS involves the presence of dual prolines near the C terminus of the SOD1 polypeptide. Indeed, the insertion of such prolines into human SOD1 rendered this molecule refractory to CCS-independent activation. The possible implications of multiple pathways for SOD1 activation are discussed in the context of SOD1 evolutionary biology and familial amyotrophic lateral sclerosis.

Early events of target deprivation/axotomy-induced neuronal apoptosis in vivo: oxidative stress, DNA damage, p53 phosphorylation and subcellular redistribution of death proteins.

The mechanisms of injury- and disease-associated apoptosis of neurons within the CNS are not understood. We used a model of cortical injury in rat and mouse to induce retrograde neuronal apoptosis in thalamus. In this animal model, unilateral ablation of the occipital cortex induces apoptosis of corticopetal projection neurons in the dorsal lateral geniculate nucleus (LGN), by 7 days post-lesion, that is p53 modulated and Bax dependent. We tested the hypothesis that this degenerative process is initiated by oxidative stress and early formation of DNA damage and is accompanied by changes in the levels of pro-apoptotic mediators of cell death. Immunoblotting revealed that the protein profiles of Bax, Bak and Bad were different during the progression of neuronal apoptosis in the LGN. Bax underwent a subcellular redistribution by 1 day post-lesion, while Bak increased later. Bad showed an early sustained increase. Cleaved caspase-3 was elevated maximally at 5 and 6 days. Active caspase-3 underwent a subcellular translocation to the nucleus. A dramatic phosphorylation of p53 was detected at 4 days post-lesion. DNA damage was assessed immunocytochemically as hydroxyl radical adducts (8-hydroxy-2-deoxyguanosine) and single-stranded DNA. Both forms of DNA damage accumulated early in target-deprived LGN neurons. Transgenic overexpression of superoxide dismutase-1 provided significant protection against the apoptosis but antioxidant pharmacotreatments with trolox and ascorbate were ineffective. We conclude that overlapping and sequential signaling pathways are involved in the apoptosis of adult brain neurons and that DNA damage generated by superoxide derivatives is an upstream mechanism for p53-regulated, Bax-dependent apoptosis of target-deprived neurons.

Mutant SOD1 causes motor neuron disease independent of copper chaperone-mediated copper loading.

Copper-mediated oxidative damage is proposed to play a critical role in the pathogenesis of Cu/Zn superoxide dismutase (SOD1)-linked familial amyotrophic lateral sclerosis (FALS). We tested this hypothesis by ablating the gene encoding the copper chaperone for SOD1 (CCS) in a series of FALS-linked SOD1 mutant mice. Metabolic 64Cu labeling in SOD1-mutant mice lacking the CCS showed that the incorporation of copper into mutant SOD1 was significantly diminished in the absence of CCS. Motor neurons in CCS-/- mice showed increased rate of death after facial nerve axotomy, a response documented for SOD1-/- mice. Thus, CCS is necessary for the efficient incorporation of copper into SOD1 in motor neurons. Although the absence of CCS led to a significant reduction in the amount of copper-loaded mutant SOD1, however, it did not modify the onset and progression of motor neuron disease in SOD1-mutant mice. Hence, CCS-dependent copper loading of mutant SOD1 plays no role in the pathogenesis of motor neuron disease in these mouse models.