Showing papers on "Motor neuron published in 1996"
TL;DR: The creation and characterization of mice completely deficient for SOD1 indicate that Cu/Zn SOD is not necessary for normal motor neuron development and function but is required under physiologically stressful conditions following injury.
Abstract: The discovery that some cases of familial amyotrophic lateral sclerosis (FALS) are associated with mutations in the gene encoding Cu/Zn superoxide dismutase (SOD1) has focused much attention on the function of SOD1 as related to motor neuron survival. Here we describe the creation and characterization of mice completely deficient for this enzyme. These animals develop normally and show no overt motor deficits by 6 months in age. Histological examination of the spinal cord reveals no signs of pathology in animals 4 months in age. However Cu/Zn SOD-deficient mice exhibit marked vulnerability to motor neuron loss after axonal injury. These results indicate that Cu/Zn SOD is not necessary for normal motor neuron development and function but is required under physiologically stressful conditions following injury.
1,305 citations
TL;DR: The ambient SHH concentration during the late period determines whether ventralized progenitors differentiate into motor neurons or interneurons, thus defining the pattern of neuronal cell types generated in the neural tube.
923 citations
TL;DR: Cell differentiation in the neural tube of embryos in which ISL1 expression has been eliminated by gene targeting shows that ISl1 is required for the generation of motor neurons and suggests that motor neuron generation is requiredfor the subsequent differentiation of certain interneurons.
778 citations
TL;DR: Large SMI-32(+) neurons are selectively damaged by prolonged (24 hr) low-level exposures to kainate or to the glutamate reuptake blockerl-trans-pyrrolidine-2,4-dicarboxylic acid, suggesting that Ca2+ ions are also important in this more slowly evolving injury.
Abstract: The nonphosphorylated neurofilament marker SMI-32 stains motor neurons in spinal cord slices and stains a subset of cultured spinal neurons ["large SMI-32(+) neurons"], which have a morphology consistent with motor neurons identified in vitro: large cell body, long axon, and extensive dendritic arborization. They are found preferentially in ventral spinal cord cultures, providing further evidence that large SMI-32(+) neurons are indeed motor neurons, and SMI-32 staining often colocalizes with established motor neuron markers (including acetylcholine, calcitonin gene-related peptide, and peripherin). Additionally, choline acetyltransferase activity (a frequently used index of the motor neuron population) and peripherin(+) neurons share with large SMI-32(+) neurons an unusual vulnerability to AMPA/kainate receptor-mediated injury. Kainate-induced loss of these motor neuron markers is Ca2+-dependent, which supports a critical role of Ca2+ ions in this injury. Raising extracellular Ca2+ exacerbates injury, whereas removal of extracellular Ca2+ is protective. A basis for this vulnerability is provided by the observation that most peripherin(+) neurons, like large SMI-32(+) neurons, are subject to kainate-stimulated Co2+ uptake, a histochemical stain that identifies neurons possessing Ca2+-permeable AMPA/kainate receptor-gated channels. Finally, of possibly greater relevance to the slow motor neuronal degeneration in diseases, both large SMI-32(+) neurons and peripherin(+) neurons are selectively damaged by prolonged (24 hr) low-level exposures to kainate (10 microM) or to the glutamate reuptake blocker L-trans-pyrrolidine-2,4-dicarboxylic acid (100 microM). During these low-level kainate exposures, large SMI-32(+) neurons showed higher intracellular Ca2+ concentrations than most spinal neurons, suggesting that Ca2+ ions are also important in this more slowly evolving injury.
447 citations
TL;DR: Because aberrant accumulation of NFs is a common pathology in a series of motor neuron diseases-including amyotrophic lateral sclerosis-NF misaccumulation, and the resultant disruption in axonal transport, is probably a key intermediate in the pathogenesis of these diseases, this work concludes that NF investment into axons is essential for establishment of axonal caliber.
Abstract: Neurofilaments (NFs) are the most abundant structural components in large-diameter myelinated axons Assembled as obligate heteropolymers requiring NF-L and substoichiometric amounts of NF-M and/or NF-H, NF investment into axons is essential for establishment of axonal caliber, itself a key determinant of conduction velocity Use of transgenic mice to increase axonal accumulation of NFs or to express mutant NFs subunits has proven that aberrant organization or assembly of NFs is sufficient to cause disease arising from selective dysfunction and degeneration of motor neurons Because aberrant accumulation of NFs is a common pathology in a series of motor neuron diseases-including amyotrophic lateral sclerosis-NF misaccumulation, and the resultant disruption in axonal transport, is probably a key intermediate in the pathogenesis of these diseases
445 citations
TL;DR: It is demonstrated that, as a part of its role in maintaining rhombomere identity, Hoxb-1 is involved in controlling migratory properties of motor neurons in the hindbrain.
Abstract: SEGMENTATION of the vertebrate hindbrain into rhombomeres is important for the anterior–posterior arrangement of cranial motor nuclei and efferent nerves1. Underlying this reiterated organization, Hox genes display segmentally restricted domains of expression2–4, such as expression of Hoxb-1 (refs 5, 6) in rhombomere 4 (r4). Here we report that absence of Hoxb-1 leads to changes in r4 identity. In mutant mouse embryos, molecular markers indicate that patterning of r4 is initiated properly but not maintained. Cellular analysis by DiI tracing reveals that the r4-specific facial branchiomotor (FBM) and contralateral vestibuloacoustic efferent (CVA) neurons are incorrectly specified. In wild-type mice CVA neurons migrate from r4 into the contralateral side7, and we found in lineage analysis that FBM neurons migrate from r4 into r5. In mutants, motor neurons differentiate but the CVA and FBM neurons fail to migrate into their proper positions. Instead, they form a motor nucleus which migrates atypically, and there is a subsequent loss of the facial motor nerve. These results demonstrate that, as a part of its role in maintaining rhombomere identity, Hoxb-1 is involved in controlling migratory properties of motor neurons in the hindbrain.
422 citations
TL;DR: Comparison studies revealed a striking similarity between the cytoskeletal pathology in the G1H transgenic mice and in patients with amyotrophic lateral sclerosis, linking a specific SOD1 mutation with alterations in the neuronal cytoskeleton of patients with Amyotrophicateral sclerosis.
Abstract: Mutations in the human Cu,Zn superoxide dismutase gene (SOD1) are found in 20% of kindreds with familial amyotrophic lateral sclerosis. Transgenic mice (line G1H) expressing a human SOD1 containing a mutation of Gly-93 --> Ala (G93A) develop a motor neuron disease similar to familial amyotrophic lateral sclerosis, but transgenic mice (line N1029) expressing a wild-type human SOD1 transgene do not. Because neurofilament (NF)-rich inclusions in spinal motor neurons are characteristic of amyotrophic lateral sclerosis, we asked whether mutant G1H and/or N1029 mice develop similar NF lesions. NF inclusions (i.e., spheroids, Lewy body-like inclusions) were first detected in spinal cord motor neurons of the G1H mice at 82 days of age about the time these mice first showed clinical evidence of disease. Other neuronal intermediate filament proteins (alpha-internexin, peripherin) also accumulated in these spheroids. The onset of accumulations of ubiquitin immunoreactivity in the G1H mice paralleled the emergence of vacuoles and NF-rich spheroids in neurons, but they did not colocalize exclusively with spheroids. In contrast, NF inclusions were not seen in the N1029 mice until they were 132 days old, and ubiquitin immunoreactivity was not increased in the N1029 mice even at 199 days of age. Astrocytosis in spinal cord was associated with a marked increase in glial fibrillary acidic protein immunoreactivity in the G1H mice, but not in the N1029 mice. Finally, comparative studies revealed a striking similarity between the cytoskeletal pathology in the G1H transgenic mice and in patients with amyotrophic lateral sclerosis. These findings link a specific SOD1 mutation with alterations in the neuronal cytoskeleton of patients with amyotrophic lateral sclerosis. Thus, neuronal cytoskeletal abnormalities may be implicated in the pathogenesis of human familial amyotrophic lateral sclerosis.
399 citations
TL;DR: These phenotypes parallel the pathologies of some vertebrate motor neuron diseases, including some forms of amyotrophic lateral sclerosis (ALS), and suggest that impaired fast axonal transport is a key element in these diseases.
Abstract: Previous work has shown that mutation of the gene that encodes the microtubule motor subunit kinesin heavy chain (Khc) in Drosophila inhibits neuronal sodium channel activity, action potentials and neurotransmitter secretion. These physiological defects cause progressive distal paralysis in larvae. To identify the cellular defects that cause these phenotypes, larval nerves were studied by light and electron microscopy. The axons of Khc mutants develop dramatic focal swellings along their lengths. The swellings are packed with fast axonal transport cargoes including vesicles, synaptic membrane proteins, mitochondria and prelysosomal organelles, but not with slow axonal transport cargoes such as cytoskeletal elements. Khc mutations also impair the development of larval motor axon terminals, causing dystrophic morphology and marked reductions in synaptic bouton numbers. These observations suggest that as the concentration of maternally provided wild-type KHC decreases, axonal organelles transported by kinesin periodically stall. This causes organelle jams that disrupt retrograde as well as anterograde fast axonal transport, leading to defective action potentials, dystrophic terminals, reduced transmitter secretion and progressive distal paralysis. These phenotypes parallel the pathologies of some vertebrate motor neuron diseases, including some forms of amyotrophic lateral sclerosis (ALS), and suggest that impaired fast axonal transport is a key element in those diseases.
374 citations
TL;DR: Results provide the first demonstration that neuronal calcium is, in fact, increased in amyotrophic lateral sclerosis in vivo, without exhibiting excess Schwann envelopment specific to denervating terminals.
Abstract: Numerous studies of amyotrophic lateral sclerosis have suggested that increased intracellular calcium is a common denominator in motoneuron injury. In experimental models, IgG from patients with amyotrophic lateral sclerosis enhanced calcium entry and induced apoptotic cell death in vitro as well as increased intracellular calcium and induced ultrastructural alterations of the motor nerve terminals in mice in vivo. To determine whether similar increases in intracellular calcium and altered morphology are present in motor nerve terminals of amyotrophic lateral sclerosis patients in vivo, muscle biopsy specimens from 7 patients with amyotrophic lateral sclerosis, 10 nondenervating disease control subjects, and 5 patients with denervating neuropathies were analyzed with ultrastructural techniques, employing oxalate-pyroantimonate fixation to preserve in situ calcium distribution. Motor nerve terminals from amyotrophic lateral sclerosis specimens contained significantly increased calcium, increased mitochondrial volume, and increased numbers of synaptic vesicles compared to any of the disease control groups, without exhibiting excess Schwann envelopment specific to denervating terminals. These results parallel the effect of amyotrophic lateral sclerosis IgG passively transferred to mice, and provide the first demonstration that neuronal calcium is, in fact, increased in amyotrophic lateral sclerosis in vivo.
317 citations
TL;DR: These results demonstrate that DPTP69D and DPTP99A are required for motor axon guidance and that they have partially redundant functions during development of the neuro-muscular system.
285 citations
TL;DR: Electrophysiological studies confirmed the slow progression and spatial distribution of clinical symptoms in the peripheral motor system and marked slowing of transmission in central motor pathways in ALS patients homozygous for an Asp90Ala mutation.
Abstract: We describe 36 patients (six were apparently sporadic cases and 30 were cases from nine families) with amyotrophic lateral sclerosis (ALS) characterized by a distinct phenotype associated with homozygosity for an Asp90Ala mutation in the CuZn-superoxide dismutase gene. The presenting motor manifestation in all patients was paresis in the legs, with slow progression to the upper extremities and finally to the bulbar muscles. The age of ALS onset varied from 20 to 94 years, with a mean of 44 years. Mean survival time was 13 years for the 11 deceased patients. However, this is probably biased and untypical (low) when compared with the disease duration in the surviving patients, and when considering other medical complications in the deceased patients. The rate of progression was highly variable, even within families. All patients showed signs of involvement of both upper and lower motor neurons. Other neurological features included painful muscle spasms and paraesthesiae in the lower extremities. Two-thirds of patients experienced difficulty with micturition. Electrophysiological studies confirmed the slow progression and spatial distribution of clinical symptoms in the peripheral motor system. Furthermore, [corrected] potentials evoked by transcranial magnetic stimulation (MEP) were compared with those evoked by cervical or lumbosacral electrical stimulation and often revealed marked slowing of transmission in central motor pathways. In Sweden and Finland ALS patients homozygous for the Asp90Ala mutation constitute a phenotypically characteristic subset of motor neuron disease.
TL;DR: Analysis of mice null for the Brn-3.0 locus shows that the gene is required for the survival of subpopulations of proprioceptive, mechanoreceptive and nociceptive sensory neu-rons, where deletion of the gene affects neurotrophin and neuro-trophin-receptor gene expression.
Abstract: SPECIFIC families of transcription factors mediate events in the sequential maturation of distinct neuronal phenotypes. Members of one such family, the class IV POU domain transcription factor Brn-3.0, and two highly related factors Brn-3.1 and Brn-3.2, are differentially expressed in the developing and mature mamma-lian nervous system1–11. The expression pattern of Brn-3.0 sug-gested that it has an important role in the development of sensory ganglia, as well as red nucleus, inferior olive, and nucleus ambiguus. Analysis of mice null for the Brn-3.0 locus shows that Brn-3.0 is required for the survival of subpopulations of proprioceptive, mechanoreceptive and nociceptive sensory neu-rons, where deletion of the gene affects neurotrophin and neuro-trophin-receptor gene expression. Deletion of Brn-3.0 also alters either differentiation, migration or survival of specific central neuronal populations.
TL;DR: Multiple neuritic populations of the adult spinal cord respond to neurotrophic factors by extending neurites, and this responsiveness is maintained and extended after major injury.
TL;DR: Findings show that BDNF and NT‐3 are survival factors for adult rat CSN in vivo, and may contribute to the development of therapeutic strategies aiming at the prevention of CSN degeneration in human motor neuron diseases.
Abstract: Brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) have been identified as survival factors for adult axotomized rat corticospinal neurons (CSN) in vivo. Axotomy of corticospinal neurons at the level of the internal capsule induced death of 46% of the CSN within the first week after axotomy. The surviving population of CSN displayed severe atrophy with mean cross-sectional area 49% of their unlesioned contralateral counterparts 7 days after axotomy. Using in situ hybridization to assess the expression of the receptors for the family of neurotrophins, we found trkB and trkC but not trkA mRNA expression in CSN. Intraparenchymal application of BDNF or NT-3 at doses of 12 microg/day for 7 days via an osmotic minipump fully prevented the axotomy-induced death of CSN. Interestingly, no neuronal atrophy was seen after BDNF application while NT-3 had only a partial effect on the size of the axotomized CSN. Nerve growth factor did not prevent death or cell atrophy, consistent with lack of trkA mRNA expression in these neurons. These findings show that BDNF and NT-3 are survival factors for adult rat CSN in vivo, and may contribute to the development of therapeutic strategies aiming at the prevention of CSN degeneration in human motor neuron diseases.
TL;DR: The nosological status of FLD-MND remains enigmatic in the absence of defined pathological and molecular markers, whereas others suggest it represents an interface between FLD and "classic" (non-dementing) motor neuron disease (CMND).
Abstract: Frontal lobe dementia (FLD) (syn frontotemporal dementia and dementia of frontal type) is a generic term that describes a clinical syndrome in which patients manifest a profound breakdown in personality and social conduct, together with adynamic spontaneous speech, culminating in mutism This pattern of cognitive impairment implicates bilateral frontal lobe dysfunction, an assumption supported by functional neuroimaging findings of anterior cerebral abnormality Patients with FLD can go on to develop motor neuron disease (FLD-MND), although the clinical features of MND may accompany or occasionally precede the onset of dementia The emergence of MND is responsible for death within 3 years of onset Frontotemporal lobar pathology in FLD-MND is characterized by loss of large cortical neurons, spongiform change and mild astrocytic gliosis Ubiquitinated (but not tau-positive) inclusions are present within the frontal cortex There is severe nigral cell loss (without Lewy bodies), and marked hypoglossal and spinal motor neuron degeneration, together with ubiquitinated (but not tau-positive) inclusions within the spinal neurons Some authors suggest that FLD-MND is a separate disease entity, whereas others suggest it represents an interface between FLD and "classic" (non-dementing) motor neuron disease (CMND) An association with CMND is supported by findings in these patients of failure in tasks sensitive to "frontal lobe" dysfunction, and patterns of functional neuroimaging abnormality which are identical in distribution, but less severe than those encountered in FLD-MND However, the nosological status of FLD-MND remains enigmatic in the absence of defined pathological and molecular markers
TL;DR: Mice constructed that express wild-type mouse NF-H up to 4.5 times the normal level are constructed to examine the mechanism through which neurofilaments regulate the caliber of myelinated axons and to test how aberrant accumulations of neurofilament cause motor neuron disease.
Abstract: To examine the mechanism through which neurofilaments regulate the caliber of myelinated axons and to test how aberrant accumulations of neurofilaments cause motor neuron disease, mice have been constructed that express wild-type mouse NF-H up to 4.5 times the normal level. Small increases in NF-H expression lead to increased total neurofilament content and larger myelinated axons, whereas larger increases in NF-H decrease total neurofilament content and strongly inhibit radial growth. Increasing NF-H expression selectively slow neurofilament transport into and along axons, resulting in severe perikaryal accumulation of neurofilaments and proximal axonal swellings in motor neurons. Unlike the situation in transgenic mice expressing modest levels of human NF-H (Cote, F., J.F. Collard, and J.P. Julien. 1993. Cell. 73:35-46), even 4.5 times the normal level of wild-type mouse NF-H does not result in any overt phenotype or enhanced motor neuron degeneration or loss. Rather, motor neurons are extraordinarily tolerant of wild-type murine NF-H, whereas wild-type human NF-H, which differs from the mouse homolog at > 160 residue positions, mediates motor neuron disease in mice by acting as an aberrant, mutant subunit.
TL;DR: All anesthetics tested appeared to depress the excitability of spinal motor neurons, and this effect may contribute to surgical immobility, and its magnitude is comparable at equipotent concentrations of agents.
Abstract: Background : Depression of spinal alpha-motor neurons apparently plays a role in the surgical immobility induced by isoflurane. Using the noninvasive technique of F-wave analysis, the authors tested the hypothesis that depressed motor neuron excitability is an effect common to other clinically relevant inhaled anesthetics. Methods : The authors measured F-wave amplitude in rats anesthetized with desflurane, enflurane, halothane, or sevoflurane. Each animal received one anesthetic at five equipotent anesthetic concentrations (0.6, 0.8, 1.2, and 1.6 minimum alveolar concentration [MAC] and 0.8 MAC with 65% N 2 O). F waves were detected as late potentials in electromyographic responses evoked in the intrinsic muscles of the hind paw after monopolar stimulation of the ipsilateral posterior tibial nerve. Results : All tested inhaled anesthetics depressed F-wave amplitude but not M-wave (orthodromic, early muscle activation) amplitude, and increased M-F latency in a dose-dependent manner. At 1.0 MAC, the estimated F/M ratio was 70 ± 13% SD of that at baseline (0.6 MAC). Nitrous oxide added to 0.8 MAC of the potent vapors depressed F/M ratio by 63 ± 17%. Conclusions : All anesthetics tested appeared to depress the excitability of spinal motor neurons. This effect may contribute to surgical immobility, and its magnitude is comparable at equipotent concentrations of agents. The authors hypothesize that this effect is due to hyperpolarization, although, currently, there is insufficient information to discriminate between pre- and postsynaptic mechanisms.
TL;DR: In 2- to 7-day chick embryos, it is found that genes of the LIM homeobox family are expressed differentially among cranial motor nuclei, consistent with a role of these transcription factors in determining neuronal phenotype and axonal pathfinding.
TL;DR: The localization and regulation of TSP immunoreactivity (TSP‐IR) during neuronal regeneration in the axotomized facial motor nucleus is examined using Western blotting and light and electron microscopy.
Abstract: Thrombospondin (TSP) is a multifunctional extracellular matrix protein that plays a role in neuronal migration and axonal outgrowth in the developing central nervous system. In the current study we have examined the localization and regulation of TSP immunoreactivity (TSP-IR) during neuronal regeneration in the axotomized facial motor nucleus using Western blotting and light and electron microscopy. Transection of the facial nerve led to a gradual increase in TSP-IR in the regenerating motoneurons, peaking 4-7 days after injury (DAI). In addition to regenerating neurons, axotomy also caused a rapid upregulation of TSP-IR on activated microglia throughout the facial nucleus, with a maximum of 2-3 DAI, and a second increase at 14-21 DAI on microglial aggregates surrounding degenerating motoneurons and in neuronophagic microglia. In summary, injury leads to the induction of thrombospondin on axotomized neurons and activated microglia, peaking at the times of maximal posttraumatic microglial proliferation and during neuronal phagocytosis. Since thrombospondin is a multimodal extracellular matrix protein with a variety of cell attachment sites, thrombospondin might serve to link microglia and injured neurons, followed by microglial proliferation and removal of the neuronal debris.
TL;DR: It is shown that FALSG93A mice suffer from motoneurone dysfunction similar to that observed in ALS patients and fulfill Lambert's criteria for ALS, and a massive loss of functional motor units starting at 47 days of age.
Abstract: Dominant mutations of human Cu/Zn superoxide dismutase (SOD1) are found in about 20% of patients with familial amyotrophic lateral sclerosis (FALS). A transgenic mouse model of FALS (FALSG93A mice) has been generated by overexpression of a mutated form of SOD1. Using electromyography we first show that FALSG93A mice suffer from motoneurone dysfunction similar to that observed in ALS patients and fulfill Lambert's criteria for ALS. We also showed that FALSG93A mice demonstrate a massive loss of functional motor units starting at 47 days of age. Impairment of motor neurone function preceeds by 6 weeks the onset of apparent clinical signs (shaking, tremor) and the beginning of motor neurone loss. Neuromuscular deficits in FALS mice do not result from motoneuronal cell death but rather from loss of axonal integrity.
TL;DR: An overview of some of the novel findings associated with lower motor neuron alterations is presented, and data regarding synaptic alterations are limited to a relatively small number of ultrastructural investigations.
Abstract: ALS is an age-associated neurodegenerative disease that primarily affects the motor neuron system. Despite having been studied for over 100 years, its etiology is still a mystery, and no specific diagnostic laboratory test has been developed. The diagnosis of ALS is therefore based on clinical features and/or neuropathologic findings. The neuropathologic findings on patients with classic ALS are quite distinct, with loss and degeneration of the large anterior horn cells of the spinal cord and lower cranial motor nuclei of the brainstem. The striated muscles display denervation atrophy. Upper motor neurons, such as the Betz cells in the motor cortex, are also affected. The several symposia and workshops on the cytopathology of ALS held within the past 3 years are a reflection of the many new and important developments taking place in this area. [1] Although loss of motor neurons has been known for many years, cytoplasmic alterations of the lower motor neurons have been studied in detail only in recent years by using immunohistochemical and electron microscopic techniques.
An overview of some of the novel findings associated with lower motor neuron alterations is presented here.
The synapse is the most important site of neuronal function and is unique to the neuron. Despite many years of extensive studies on ALS, data regarding synaptic alterations are limited to a relatively small number of ultrastructural investigations. [2] This paucity of information is due to the inherent difficulties that affect the proper evaluation of synapses in autopsy material.
Synaptophysin, a 38-kDa glycoprotein, is a constituent of the membrane of synaptic vesicles in presynaptic terminals. The evaluation of synaptophysin expression in the lumbar spinal cord of ALS patients was apparently presented for the first time by Kawanami et al. [3] at the Annual Meeting of the Canadian Association of Neuropathologists in September 1992. This …
TL;DR: EMG patterns evoked by voluntary and passive maneuvers and by volitional modulation of reflex responses reveal features of motor control not apparent in the clinical examination, which may explain paradoxically different responses in apparently similar SCI subjects.
Abstract: The brain motor control assessment (BMCA) protocol is a comprehensive multichannel surface EMG recording used to characterize motor control features in persons with upper motor neuron dysfunction Key information is contained in the overall temporal pattern of motor unit activity, observed in the EMG (RMS) envelope In paralysis, a rudimentary form of suprasegmental control of tonic and phasic reflexes can be demonstrated EMG patterns evoked by voluntary and passive maneuvers and by volitional modulation of reflex responses reveal features of motor control not apparent in the clinical examination Such subclinical findings may explain paradoxically different responses in apparently similar SCI subjects, and may be used to monitor spontaneous or induced changes The recording protocol, examples of EMG patterns, and their prevalence in 40 spinal cord injured (SCI) subjects are presented, and compared with 5 healthy subjects
TL;DR: Additional mice expressing point mutations in the cytoplasmic enzyme superoxide dismutase (SOD1), the only known cause of ALS, have proved that disease arises from a toxic property of the mutant enzyme rather than loss of enzyme activity.
Abstract: Concerning the mechanism(s) of disease underlying amyotrophic lateral sclerosis (ALS), transgenic mouse models have provided (i) a detailed look at the pathogenic progression of disease, (ii) a tool for testing hypotheses concerning the mechanism of neuronal death, and (iii) a host appropriate for testing therapeutic strategies. Thus far, these efforts have proved that mutation in a neurofilament subunit can cause progressive disease displaying both selective motor neuron death and aberrant neurofilament accumulation similar to that reported in human disease. Additional mice expressing point mutations in the cytoplasmic enzyme superoxide dismutase (SOD1), the only known cause of ALS, have proved that disease arises from a toxic property of the mutant enzyme rather than loss of enzymatic activity.
TL;DR: The results suggest that the apolipoprotein E ∈4 allele may influence the pattern of motor neuron loss in motor neuron disease and that it may affect neuronal function in ways unrelated to the deposition of β-amyloid or accumulation of neurofibrillary tangles.
TL;DR: A 51‐year‐old man in whom weakness heralded the presence of a small‐cell cancer of the lung was reported, in whom objective measures of strength nor titers of anti‐Hu antibody responded to corticosteroids, cyclophosphamide, intravenous immunoglobulins, or plasmapheresis.
Abstract: Although isolated lower motor neuron disease has been reported as a paraneoplastic complication, it has not been previously described, in association with anti-Hu antibody. We report a 51-year-old man in whom weakness heralded the presence of a small-cell cancer of the lung. His neurological disorder was characterized by an unremitting progression of limb, neck, and chest wall weakness and wasting that commenced and remained predominant in the upper limbs. Electrophysiological studies demonstrated widespread denervation and examination of a muscle biopsy specimen showed evidence of acute and chronic denervation. High titers of anti-Hu antibody were detected in the serum and cerebrospinal fluid. Neither objective measures of strength nor titers of anti-Hu antibody responded to corticosteroids, cyclophosphamide, intravenous immunoglobulins, or plasmapheresis. Death from the complications of motor neuron disease ensued 23 months after the onset of weakness. Autopsy revealed tumor in the lung and on pleural and peritoneal surfaces. There was a loss of anterior horn cells in the spinal cord. Despite the absence of symptomatic cerebellar disease, a decrease in the number of Purkinje cells was also detected.
TL;DR: The observation that the stretch reflex is proportionally more depressed than the H-reflex is consistent with fusimotor drive also being depressed after SCI, which is a major physiologic derangement in spinal shock.
Abstract: Background: Few studies in humans have assessed the ability of Ia afferent and antidromic motor volleys to activate motoneurons during spinal shock. Hence, little is known about the excitability state of the spinal motoneuron pool after acute spinal cord injury (SCI) in humans. Methods: In 14 patients with acute SCI involving anatomic levels T10 and above, we performed clinical and electrophysiologic studies early after injury (within 24 hours in seven subjects) and on day 10, 20, and 30 postinjury. Maximal H:M ratios, F-wave persistence, and tendon tap T-reflexes were recorded. Sixteen normal subjects and eight chronic SCI patients served as control subjects. Results: Ten of 14 patients had spinal shock (complete paralysis, loss of sensation, absent reflexes, and muscle hypotonia below the injury) at the time of initial evaluation. F-waves were absent in patients with spinal shock, reduced in persistence in patients with acute SCI without spinal shock, and normal in persistence in patients with chronic SCI. H-reflexes were absent or markedly suppressed in patients with spinal shock within 24 hours of injury but recovered to normal amplitudes within several days postinjury. This recovery occurred despite absence of F-waves that persisted for several weeks postinjury. Deep tendon reflexes were proportionally more depressed in spinal shock than were H-reflexes. All patients had elicitable H-reflexes for days or weeks before the development of clinical reflexes. Conclusions: Rostral cord injury causes postsynaptic changes (hyperpolarization) in caudal motoneurons. This hyperpolarization is a major physiologic derangement in spinal shock. The rise in H-reflex amplitude despite evidence of persistent hyperpolarization is due to enhanced transmission at Ia fiber-motoneuron connections below the SCI. Finally, the observation that the stretch reflex is proportionally more depressed than the H-reflex is consistent with fusimotor drive also being depressed after SCI. NEUROLOGY 1996;47: 231-237
TL;DR: To examine whether mutation in neurofilament subunits causes or predisposes to ALS, single‐strand conformation polymorphism coupled with DNA sequencing was used to search for mutations in the entirety of the human NF‐L, NF‐M, and NF‐H genes from 100 familial ALS patients known not to carry mutations in superoxide dismutase 1 (SOD1), as well as from 75 sporadic ALS patients.
Abstract: Neurofilaments, assembled from NF-L (68 kd), NF-M (95 kd), and NF-H (115 kd), are the most abundant structural components in large myelinated axons, particularly those of motor neurons. Aberrant neurofilament accumulation in cell bodies and axons of motor neurons is a prominent pathological feature of several motor neuron diseases, including sporadic and familial amyotrophic lateral sclerosis (ALS). Transgenic methods have proved in mice that mutation in or increased expression of neurofilament subunits can be primary causes of motor neuron disease that mimics the neurofilamentous pathology often reported in human disease. To examine whether mutation in neurofilament subunits causes or predisposes to ALS, we used single-strand conformation polymorphism coupled with DNA sequencing to search for mutations in the entirety of the human NF-L, NF-M, and NF-H genes from 100 familial ALS patients known not to carry mutations in superoxide dismutase 1 (SOD1), as well as from 75 sporadic ALS patients. Six polypeptide sequence variants were identified in rod and tail domains of NF-L, NF-M, or NF-H. However, all were found at comparable frequency in DNAs from normal individuals and no variant cosegregated with familial disease. Two deletions found previously in NF-H genes of sporadic ALS patients were not seen in this group of familial or sporadic ALS patients.
TL;DR: It is concluded that central mechanisms can establish the timing and patterning of the crawling motor pattern and that crawling may reflect the output of a central pattern generating network.
Abstract: 1. Larval crawling is a bilaterally symmetrical behavior that involves an anterior moving wave of motor activity in the body wall muscles in conjunction with sequential movements of the abdominal prolegs and thoracic legs. The purpose of this study was to determine whether the larval CNS by itself and without phasic sensory feedback was capable of producing patterned activity associated with crawling. To establish the extent of similarity between the output of the isolated nerve cord and crawling, the motor activity produced in isolated larval nerve cords was compared with the motor activity from freely crawling larvae. 2. When exposed to the muscarinic receptor agonist pilocarpine (1.0 mM), isolated larval nerve cords produced long-lasting rhythmic activity in the motor neurons that supply the thoracic leg, abdominal body wall, and abdominal proleg muscles. The rhythmic activity evoked by pilocarpine was abolished reversibly and completely by bath application of the muscarinic-receptor antagonist atropine (0.01 mM) in conjunction with pilocarpine (1.0 mM), suggesting that the response was mediated by muscarinic-like acetylcholine receptors. 3. Similar to crawling in intact animals, the evoked activity in isolated nerve cords involved bilaterally symmetrical motor activity that progressed from the most posterior abdominal segment to the most anterior thoracic segment. The rhythmic activity in thoracic leg, abdominal proleg, and abdominal body wall motor neurons showed intrasegmental and intersegmental cycle-to-cycle coupling. The average cycle period for rhythmic activity in the isolated nerve cord was approximately 2.5 times slower than the cycle period for crawling in intact larvae, but not more variable. 4. Like crawling in intact animals, in isolated nerve cords, bursting activity in the dorsal body wall motor neurons occurred before activity in ventral/lateral body wall motor neurons within an abdominal segment. The evoked bursting activity recorded from the proleg nerve was superimposed on a high level of tonic activity. 5. In isolated nerve cords, bursts of activity in the thoracic leg levator/extensor motor neurons alternated with bursts of activity in the depressor/flexor motor neurons. The burst duration of the levator/extensor activity was brief and remained relatively steady as cycle period increased. The burst duration of the depressor/ flexor activity occupied the majority of an average cycle and increased as cycle period increased. The phase of both levator/extensor motor nerve activity and depressor/flexor motor nerve activity remained relatively stable over the entire range of cycle periods. The timing and patterning of thoracic leg motor neuron activity in isolated nerve cords quantitatively resembled thoracic leg motor activity in freely crawling larvae. 6. The rhythmic motor activity generated by an isolated larval nerve cord resembled a slower version of normal crawling in intact larvae. Because of the many similarities between activity induced in the isolated nerve cord and the muscle activity and movements of thoracic and abdominal segments during crawling, we concluded that central mechanisms can establish the timing and patterning of the crawling motor pattern and that crawling may reflect the output of a central pattern generating network.
TL;DR: The results indicate that small neurons widely distributed in the intermediate zone of the ventral horn significantly diminished with aging, whereas medium-sized and large neurons located in the medial and lateral nuclei showed only a slight decrease with advancing age.
Abstract: A cytoarchitectonic study of spinal ventral horn cells was performed to identify age-related changes. The diameter distribution of ventral horn neurons of the fourth lumbar segment of the spinal cord and their size and topographical distributions were investigated in 14 autopsy cases. These cases represented patients of 18–100 years of age who had died of non-neurological diseases. The results indicate that small neurons widely distributed in the intermediate zone of the ventral horn significantly diminished with aging (P < 0.0005, r = –0.898), whereas medium-sized and large neurons located in the medial and lateral nuclei showed only a slight decrease with advancing age. The total number of neurons in the whole ventral horn was also noted to decrease significantly with aging (P < 0.0005, r = –0.899). While small neurons in the intermediate zone of the ventral horn are thought to be mostly interneurons, their physiological function still remains obscure in many respects. The findings of this study provide insight into age-related cell loss in terms of size and location.
TL;DR: Clinical, radiological, neurophysiological and pathological findings all point to a predominantly, but not exclusively, motor radiculopathy affecting the irradiated portion of the cauda equina proximal to the dorsal root ganglia.
Abstract: It is not known whether the post-irradiation lower motor neuron syndrome results from radiation damage to motor neuron cell bodies or from damage to the nerve roots of the cauda equina. We studied six cases who had presented with testicular neoplasms, subsequently undergoing irradiation that encompassed inter alia para-aortic nodes with co-irradiation of the distal spinal cord and cauda equina. A predominantly motor disorder affecting the legs ensued after variable and often prolonged latencies (3-25 years). However, all patients also developed mild sensory features either initially or on prolonged follow-up. Sural sensory nerve action potentials (SNAPs) were normal in five. Mild sphincter symptoms occurred in three of five surviving cases after a mean of 7.9 years. MRI showed gadolinium enhancement of the cauda equina in two of three patients. The first reported neuropathological study, uncomplicated by metastatic disease, of the conus and cauda equina was performed in one patient who died. This showed a radiation-induced vasculopathy of the proximal spinal roots, with preservation of motor neuronal cell bodies and spinal cord architecture. These clinical, radiological, neurophysiological and pathological findings all point to a predominantly, but not exclusively, motor radiculopathy affecting the irradiated portion of the cauda equina proximal to the dorsal root ganglia. Radiation exposure exceeded 40 Gy both in our series and in previous reports. The natural history of this disorder is one of relentless deterioration occasionally punctuated by 1-2-year periods of stability. Post-irradiation lumbosacral radiculopathy is a more accurate name for this condition.