Motor neuron degeneration after sciatic nerve avulsion in adult rat evolves with oxidative stress and is apoptosis.

The mechanisms for motor neuron degeneration and regeneration in adult spinal cord following axotomy and target deprivation are not fully understood. We used a unilateral sciatic nerve avulsion model in adult rats to test the hypothesis that retrograde degeneration of motor neurons resembles apoptosis. By 21 days postlesion, the number of large motor neurons in lumbar spinal cord was reduced by approximately 30%. The death of motor neurons was confirmed using the terminal transferase-mediated deoxyuridine triphosphate-biotin nick-end labeling method for detecting fragmentation of nuclear DNA. Motor neuron degeneration was characterized by aberrant accumulation of perikaryal phosphorylated neurofilaments. Structurally, motor neuron death was apoptosis. Apoptotic motor neurons undergo chromatolysis followed by progressive cytoplasmic and nuclear condensation with chromatin compaction into uniformly large round clumps. Prior to apoptosis, functionally active mitochondria accumulate within chromatolytic motor neurons, as determined by cytochrome c oxidase activity. These dying motor neurons sustain oxidative damage to proteins and nucleic acids within the first 7 days after injury during the progression of apoptosis, as identified by immunodetection of nitrotyrosine and hydroxyl-modified deoxyguanosine and guanosine. We conclude that the retrograde death of motor neurons in the adult spinal cord after sciatic nerve avulsion is apoptosis. Accumulation of active mitochondria within the perikaryon and oxidative damage to nucleic acids and proteins may contribute to the mechanisms for apoptosis of motor neurons in the adult spinal cord.     

Retinoid receptors in chronic degeneration of the spinal cord: observations in a rat model of amyotrophic lateral sclerosis

Changes in distribution and expression of retinoid receptors may be part of a spinal cord protective response to acute injury and to chronic degeneration. In this study, we have combined RNA and protein expression analysis to characterize the expression profile of retinoid receptors in the lumbar spinal cord of the superoxide dismutase 1 G93A mutant rat model of amyotrophic lateral sclerosis, a fatal neurodegenerative disorder causing extensive motor neuron loss. We also report a nonsignificant change in RNA expression of binding proteins and metabolizing enzymes for retinol and retinoic acid in the mutant rat spinal cord at end-stage disease. Only retinoid X receptor beta (RXRbeta), and to a lesser extent retinoic acid receptor beta and alpha (RARbeta/alpha) were reliably detected in lumbar spinal cord at an early pre-symptomatic phase and throughout the disease progression. The expression of RXRbeta in lamina II neurons in the dorsal horn of transgenic and wild type (WT) animals was associated with extensive astrocyte staining in end-stage lumbar spinal cord from transgenic rats. RARbeta and RARalpha diffuse staining of large motor neurons in the pre-symptomatic transgenic and in the WT lumbar cord appear to decline in end-stage disease, when a selective and strong gamma motor neuron RARalpha staining becomes evident. As gliosis and motor neuron loss are key pathogenic features in amyotrophic lateral sclerosis, the selective expression of retinoid receptors in astrocytes and motor neurons may provide further clues to the role of retinoid signalling in neurodegeneration and suggest new treatment strategies based on retinoid-modulating agents.     

T-588 Protects Motor Neuron Death Following Axotomy

R(-)-1-(benzo [b] thiophen-5-yl)-2-[2-(N,N-diethylamino)ethoxy] ethanol hydrochloride) (T-588) enhances acetylcholine release. This compound slows the motor deterioration of wobbler mouse motor neuron disease and enhances neurite outgrowth and choline acetyltransferase activity in cultured rat spinal motor neurons. We examined the ability of T-588 on axotomized spinal motor neuron death in the rat spinal cord. After the postnatal unilateral section of sciatic nerve, there was approximately a 50% survival of motor neurons in the fourth lumbar segment. In comparison with vehicle, intraperitoneal injection of T-588 for 14 consecutive days rescued spinal motor neuron death. Our results showing in vivo neurotrophic activity of T-588 for motor neurons support the applicability of T-588 for the treatment of motor neuron diseases, such as amyotrophic lateral sclerosis and motor neuropathies.     

Motor neuron degeneration after sciatic nerve avulsion in adult rat evolves with oxidative stress and is apoptosis

The mechanisms for motor neuron degeneration and regeneration in adult spinal cord following axotomy and target deprivation are not fully understood. We used a unilateral sciatic nerve avulsion model in adult rats to test the hypothesis that retrograde degeneration of motor neurons resembles apoptosis. By 21 days postlesion, the number of large motor neurons in lumbar spinal cord was reduced by ∼30%. The death of motor neurons was confirmed using the terminal transferase‐mediated deoxyuridine triphosphate‐biotin nick‐end labeling method for detecting fragmentation of nuclear DNA. Motor neuron degeneration was characterized by aberrant accumulation of perikaryal phosphorylated neurofilaments. Structurally, motor neuron death was apoptosis. Apoptotic motor neurons undergo chromatolysis followed by progressive cytoplasmic and nuclear condensation with chromatin compaction into uniformly large round clumps. Prior to apoptosis, functionally active mitochondria accumulate within chromatolytic motor neurons, as determined by cytochrome c oxidase activity. These dying motor neurons sustain oxidative damage to proteins and nucleic acids within the first 7 days after injury during the progression of apoptosis, as identified by immunodetection of nitrotyrosine and hydroxyl‐modified deoxyguanosine and guanosine. We conclude that the retrograde death of motor neurons in the adult spinal cord after sciatic nerve avulsion is apoptosis. Accumulation of active mitochondria within the perikaryon and oxidative damage to nucleic acids and proteins may contribute to the mechanisms for apoptosis of motor neurons in the adult spinal cord. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 185–201, 1999     

Fibroblast growth factor-1 induces heme oxygenase-1 via nuclear factor erythroid 2-related factor 2 (Nrf2) in spinal cord astrocytes: consequences for motor neuron survival

Fibroblast growth factor-1 (FGF-1) is highly expressed in motor neurons and can be released in response to sublethal cell injury. Because FGF-1 potently activates astroglia and exerts a direct neuroprotection after spinal cord injury or axotomy, we examined whether it regulated the expression of inducible and cytoprotective heme oxygenase-1 (HO-1) enzyme in astrocytes. FGF-1 induced the expression of HO-1 in cultured rat spinal cord astrocytes, which was dependent on FGF receptor activation and prevented by cycloheximide. FGF-1 also induced Nrf2 mRNA and protein levels and prompted its nuclear translocation. HO-1 induction was abolished by transfection of astrocytes with a dominant-negative mutant Nrf2, indicating that FGF-1 regulates HO-1 expression through Nrf2. FGF-1 also modified the expression of other antioxidant genes regulated by Nrf2. Both Nrf2 and HO-1 levels were increased and co-localized with reactive astrocytes in the degenerating lumbar spinal cord of rats expressing the amyotrophic lateral sclerosis-linked SOD1 G93A mutation. Overexpression of Nrf2 in astrocytes increased survival of co-cultured embryonic motor neurons and prevented motor neuron apoptosis mediated by nerve growth factor through p75 neurotrophin receptor. Taken together, these results emphasize the key role of astrocytes in determining motor neuron fate in amyotrophic lateral sclerosis.     

The prostate apoptosis response-4 protein participates in motor neuron degeneration in amyotrophic lateral sclerosis.

Prostate apoptosis response-4 (Par-4), a protein containing a leucine zipper domain within a death domain, is up-regulated in prostate cancer cells and hippocampal neurons induced to undergo apoptosis. Here, we report higher Par-4 levels in lumbar spinal cord samples from patients with amyotrophic lateral sclerosis (ALS) than in lumbar spinal cord samples from neurologically normal patients. We also compared the levels of Par-4 in lumbar spinal cord samples from wild-type and transgenic mice expressing the human Cu/Zn-superoxide dismutase gene with a familial ALS mutation. Relative to control samples, higher Par-4 levels were observed in lumbar spinal cord samples prepared from the transgenic mice at a time when they had hind-limb paralysis. Immunohistochemical analyses of human and mouse lumbar spinal cord sections revealed that Par-4 is localized to motor neurons in the ventral horn region. In culture studies, exposure of primary mouse spinal cord motor neurons or NSC-19 motor neuron cells to oxidative insults resulted in a rapid and large increase in Par-4 levels that preceded apoptosis. Pretreatment of the motor neuron cells with a Par-4 antisense oligonucleotide prevented oxidative stress-induced apoptosis and reversed oxidative stress-induced mitochondrial dysfunction that preceded apoptosis. Collectively, these data suggest a role for Par-4 in models of motor neuron injury relevant to ALS.     

Motor neuronal protection by l-arginine prolongs survival of mutant SOD1 (G93A) ALS mice

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disorder characterized by progressive paralysis due to motor neuron degeneration. Despite the fact that many different therapeutic strategies have been applied to prevent disease progression, no cure or effective therapy is currently available for ALS. We found that l-arginine protects cultured motor neurons from excitotoxic injury. We also found that l-arginine supplementation both prior to and after the onset of motor neuron degeneration in mtSOD1 (G93A) transgenic ALS mice significantly slowed the progression of neuropathology in lumbar spinal cord, delayed onset of motor dysfunction, and prolonged life span. Moreover, l-arginine treatment was associated with preservation of arginase I activity and neuroprotective polyamines in spinal cord motor neurons. Our findings show that l-arginine has potent in vitro and in vivo neuroprotective properties and may be a candidate for therapeutic trials in ALS.     

Motor unit abnormalities in Dystonia musculorum mice

Dystonia musculorum (dt) is a mouse inherited sensory neuropathy caused by mutations in the dystonin gene. While the primary pathology lies in the sensory neurons of dt mice, the overt movement disorder suggests motor neurons may also be affected. Here, we report on the contribution of motor neurons to the pathology in dt(27J) mice. Phenotypic dt(27J) mice display reduced alpha motor neuron cell number and eccentric alpha motor nuclei in the ventral horn of the lumbar L1 spinal cord region. A dramatic reduction in the total number of motor axons in the ventral root of postnatal day 15 dt(27J) mice was also evident. Moreover, analysis of the trigeminal nerve of the brainstem showed a 2.4 fold increase in number of degenerating neurons coupled with a decrease in motor neuron number relative to wild type. Aberrant phosphorylation of neurofilaments in the perikaryon region and axonal swellings within the pre-synaptic terminal region of motor neurons were observed. Furthermore, neuromuscular junction staining of dt(27J) mouse extensor digitorum longus and tibialis anterior muscle fibers showed immature endplates and a significant decrease in axon branching compared to wild type littermates. Muscle atrophy was also observed in dt(27J) muscle. Ultrastructure analysis revealed amyelinated motor axons in the ventral root of the spinal nerve, suggesting a possible defect in Schwann cells. Finally, behavioral analysis identified defective motor function in dt(27J) mice. This study reveals neuromuscular defects that likely contribute to the dt(27J) pathology and identifies a critical role for dystonin outside of sensory neurons.     

Hoxa10 and Hoxd10 coordinately regulate lumbar motor neuron patterning

The paralogous Hox genes Hoxa10 and Hoxd10 are expressed in overlapping domains in the developing lumbar spinal cord and surrounding mesoderm. Independent inactivation of these two genes alters the trajectory of spinal nerves and decreases the complement of motor neurons present in the lumbar spinal cord, whereas dual inactivation of these two genes has been shown to alter peripheral nerve growth and development in the mouse hindlimb. We have examined the organization and distribution of lumbar motor neurons in the spinal cords of Hoxa10/Hoxd10 double mutant animals. Double mutant animals have decreased numbers of lumbar motor neurons in both the medial and lateral motor columns. The anteroposterior position of the lumbar motor column is shifted caudally in double mutant animals, and the distribution of motor neurons is altered across individual spinal segments. Distinctions between classes of motor neurons based on positional specificity appear disrupted in double mutants. Double mutants also demonstrate abnormal spinal cord vasculature and altered kidney placement and size. Our observations suggest that Hoxa10 and Hoxd10 activity is required to specify the position of the lumbar motor column and to provide segmental specification and identity for the lumbar motor neurons.     

脊髓薄片器官型培养的方法研究（简报）

脊髓的器官培养技术是借助体外培养技术,将脊髓或其一部分分离出来进行培养、研究的技术。因其保留有脊髓神经元及其周围的组织结构,与体内的生理环境相似,是探讨脊髓形态发生、构筑特点、生理功能及病理改变等问题的一条重要途径,在近年来得到飞速发展,成为国际神经科领域的一大研究热点。本文旨在利用脊髓薄片器官型培养技     

谷氨酸转运抑制剂对器官型培养脊髓片的影响

观察谷氨酸转运体抑制剂苏一羟天冬氨酸(Threo-hydroxyaspartate,THA)对器官型培养的脊髓片的影响,探讨谷氨酸在运动神经元损伤中的作用。取出生后8天乳鼠的腰段脊髓组织切片做脊髓器官型培养,在培养液中加入不同浓度THA(50μmol／L、100μmol／L、5001μmol／L),用神经元的特异性免疫组化染色剂SMI-32,非磷酸化神经丝标记物,对脊髓腹角α运动神经元进行鉴定,用单克隆抗钙网膜蛋白(calretinin)抗体对背角中间神经元进行记数,测定培养液中乳酸脱氢酶(LDH)的含量,并与对照组比较。结果显示对照组α运动神经元数目恒定,THA可以引起剂量依赖性的培养液中LDH含量增高和α运动神经元数目减少,而脊髓背角的中间神经元损伤相对较轻,其中THA100μmol／L组在体外培养4周后出现类似于肌萎缩侧索硬化(ALS)的病理改变：α运动神经元数目较对照组明显减少,而脊髓背角的中间神经元数目无显著变化。细胞外谷氨酸增高主要对运动神经元造成损伤,脊髓运动神经元较感觉神经元对谷氨酸的兴奋毒作用更加敏感。     

Glial activation and TNFR-I upregulation precedes motor dysfunction in the spinal cord of mnd mice

Mice homozygous for the spontaneous motor neuron degeneration mutation (mnd) show at the age of 8 months a marked impairment of the motor function and accumulation of lipofuscin granules in the cytoplasm of almost all neurons of the central nervous system.We previously reported a significant increase in GFAP protein levels in the lumbar spinal cord homogenates by western blot analysis and upregulation of TNF, a proinflammatory cytokine, in the motor neurons of lumbar spinal cord of mnd mice, already in a presymptomatic stage (4 months of age). In the present study, using immunohistochemical analysis, we performed a time course in mnd mice (1, 4 and 9 months of age) evaluating the expression and the distribution of astroglial and microglial cells and the expression of both TNF receptors, TNFR-I and TNFR-II. We observed a marked increase in astroglial and microglial cells and in TNFR-I immunoreactivity already at the 4th month. Since motor neuron dysfunction occurs in mnd mice in the absence of evident loss of spinal motor neurons, the present results indicate that the activation of microglial cells and astrocytes is independent from neuronal degeneration. The role of TNF and TNFR-I on motor neurons is still to be demonstrated.     

P2X7 receptor‐induced death of motor neurons by a peroxynitrite/FAS‐dependent pathway

The P2X7 receptor/channel responds to extracellular ATP and is associated with neuronal death and neuroinflammation in spinal cord injury and amyotrophic lateral sclerosis. Whether activation of P2X7 directly causes motor neuron death is unknown. We found that cultured motor neurons isolated from embryonic rat spinal cord express P2X7 and underwent caspase‐dependent apoptosis when exposed to exceptionally low concentrations of the P2X7 agonist 2′(3′)‐O‐(4‐Benzoylbenzoyl)‐ATP. The P2X7 inhibitors BBG, oATP, and KN‐62 prevented 2′(3′)‐O‐(4‐Benzoylbenzoyl)‐ATP‐induced motor neuron death. The endogenous P2X7 agonist ATP induced motor neuron death at low concentrations (1‐100 μM). High concentrations of ATP (1 mM) paradoxically became protective due to degradation in the culture media to produce adenosine and activate adenosine receptors. P2X7‐induced motor neuron death was dependent on neuronal nitric oxide synthase‐mediated production of peroxynitrite, p38 activation, and autocrine FAS signaling. Taken together, our results indicate that motor neurons are highly sensitive to P2X7 activation, which triggers apoptosis by activation of the well‐established peroxynitrite/FAS death pathway in motor neurons.     

Injury-induced spinal motor neuron apoptosis is preceded by DNA single-strand breaks and is p53- and Bax-dependent.

The mechanisms of injury-induced apoptosis of neurons within the spinal cord are not understood. We used a model of peripheral nerve-spinal cord injury in the rat and mouse to induce motor neuron degeneration. In this animal model, unilateral avulsion of the sciatic nerve causes apoptosis of motor neurons. We tested the hypothesis that p53 and Bax regulate this neuronal apoptosis, and that DNA damage is an early upstream signal. Adult mice and rats received unilateral avulsions causing lumbar motor neurons to achieve endstage apoptosis at 7-14 days postlesion. This motor neuron apoptosis is blocked in bax(-/-) and p53(-/-) mice. Single-cell gel electrophoresis (comet assay), immunocytochemistry, and quantitative immunogold electron microscopy were used to measure molecular changes in motor neurons during the progression of apoptosis. Injured motor neurons accumulate single-strand breaks in DNA by 5 days. p53 accumulates in nuclei of motor neurons destined to undergo apoptosis. p53 is functionally activated by 4-5 days postlesion, as revealed by immunodetection of phosphorylated p53. Preapoptotically, Bax translocates to mitochondria, cytochrome c accumulates in the cytoplasm, and caspase-3 is activated. These results demonstrate that motor neuron apoptosis in the adult spinal cord is controlled by upstream mechanisms involving DNA damage and activation of p53 and downstream mechanisms involving upregulated Bax and cytochrome c and their translocation, accumulation of mitochondria, and activation of caspase-3. We conclude that adult motor neuron death after nerve avulsion is DNA damage-induced, p53- and Bax-dependent apoptosis.     

Cloning and characterization of rat neuronal apoptosis inhibitory protein cDNA

The human neuronal apoptosis inhibitory protein (NAIP) gene was originally discovered because of its deletion in infantile spinal muscular atrophy (SMA), a childhood genetic disorder characterized by motor neuron loss and progressive paralysis with muscular atrophy. Although SMA is now known to be caused by deletions of survival motor neuron (SMN), the fact that NAIP is an anti-apoptotic protein is consistent with the NAIP gene modifying SMA severity. Here we report the cloning of a 1.5 kb rat NAIP cDNA fragment which contains BIR-3 (third baculovirus inhibitory repeat) domain. This fragment shows 78% homology to the human NAIP and 86% homology to the murine counterpart. We have investigated the distribution of NAIP mRNA expressing neurons by in situ RT-PCR technique in the rat central nervous system (CNS). Although all of the neurons appeared to express NAIP mRNA ubiquitously, pronounced elevation of NAIP mRNA expression was observed in the areas innervated by glutamatergic neurons after kainic acid (KA) injection. We have raised an anti-rat NAIP antiserum in rabbits using NAIP cDNA and recombinant rat NAIP, and carried out an immunohistological investigation. We observed highly immunoreactive neuronal subpopulations in the retinal ganglion, cerebral cortex, hippocampus, basal forebrain, thalamus, areas of midbrain, Purkinje cells of the cerebellum, and motor neurons in the spinal cord. Increased immunoreactivity of glutamatergic neurons was also observed broadly in the CNS after KA treatment. This study provides additional evidence that expression of mRNA and gene products of NAIP seem to be regulated in response to excessive stimuli or injuries in rat CNS, and these results are compatible with an anti-apoptotic role of NAIP in acute SMA as well as in brain injuries.     

Selective Vulnerability of Spinal and Cortical Motor Neuron Subpopulations in delta7 SMA Mice

Loss of the survival motor neuron gene (SMN1) is responsible for spinal muscular atrophy (SMA), the most common inherited cause of infant mortality. Even though the SMA phenotype is traditionally considered as related to spinal motor neuron loss, it remains debated whether the specific targeting of motor neurons could represent the best therapeutic option for the disease. We here investigated, using stereological quantification methods, the spinal cord and cerebral motor cortex of ∆7 SMA mice during development, to verify extent and selectivity of motor neuron loss. We found progressive post-natal loss of spinal motor neurons, already at pre-symptomatic stages, and a higher vulnerability of motor neurons innervating proximal and axial muscles. Larger motor neurons decreased in the course of disease, either for selective loss or specific developmental impairment. We also found a selective reduction of layer V pyramidal neurons associated with layer V gliosis in the cerebral motor cortex. Our data indicate that in the ∆7 SMA model SMN loss is critical for the spinal cord, particularly for specific motor neuron pools. Neuronal loss, however, is not selective for lower motor neurons. These data further suggest that SMA pathogenesis is likely more complex than previously anticipated. The better knowledge of SMA models might be instrumental in shaping better therapeutic options for affected patients.     

Activation of divergent neuronal cell death pathways in different target cell populations during neuroadapted sindbis virus infection of mice

Infection of adult mice with neuroadapted Sindbis virus (NSV) results in a severe encephalomyelitis accompanied by prominent hindlimb paralysis. We find that the onset of paralysis parallels morphologic changes in motor neuron cell bodies in the lumbar spinal cord and in motor neuron axons in ventral nerve roots, many of which are eventually lost over time. However, unlike NSV-induced neuronal cell death found in the brain of infected animals, the loss of motor neurons does not appear to be apoptotic, as judged by morphologic and biochemical criteria. This may be explained in part by the lack of detectable caspase-3 expression in these cells.     

Human Motor Neurons Generated from Neural Stem Cells Delay Clinical Onset and Prolong Life in ALS Mouse Model

Amyotrophic lateral sclerosis (ALS) is the most common adult onset motor neuron disease. The etiology and pathogenic mechanisms of the disease remain unknown, and there is no effective treatment. Here we show that intrathecal transplantation of human motor neurons derived from neural stem cells (NSCs) in spinal cord of the SOD1G93A mouse ALS model delayed disease onset and extended life span of the animals. When HB1.F3.Olig2 (F3.Olig2) cells, stable immortalized human NSCs encoding the human Olig2 gene, were treated with sonic hedgehog (Shh) protein for 5–7 days, the cells expressed motor neuron cell type-specific phenotypes Hb9, Isl-1 and choline acetyltransferase (ChAT). These F3.Olig2-Shh human motor neurons were transplanted intrathecally in L5–L6 spinal cord of SOD1G93A mice, and at 4 weeks post-transplantation, transplanted F3.Olig2-Shh motor neurons expressing the neuronal phenotype markers NF, MAP2, Hb9, and ChAT were found in the ventral horn of the spinal cord. Onset of clinical signs in ALS mice with F3.Olig2-Shh motor neuron implants was delayed for 7 days and life span of animals was significantly extended by 20 days. Our results indicate that this treatment modality of intrathecal transplantation of human motor neurons derived from NSCs might be of value in the treatment of ALS patients without significant adverse effects.