SMI-32 antibody against non-phosphorylated neurofilaments identifies a subpopulation of cultured cortical neurons hypersensitive to kainate toxicity

Neuronal densities and vascular pathology in the hippocampal formation in CADASIL

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is the most common form of hereditary cerebral small vessel disease. Previous neuroimaging studies have suggested loss of hippocampal volume is a pathway for cognitive impairment in CADASIL. We used unbiased stereological methods to estimate SMI32-positive and total numbers and volumes of neurons in the hippocampal formation of 12 patients with CADASIL and similar age controls (young controls) and older controls. We found densities of SMI32-positive neurons in the entorhinal cortex, layer V, and cornu ammonis CA2 regions were reduced by 26%–50% in patients with CADASIL compared with young controls (p < 0.01), with a decreasing trend observed in older controls in the order of young controls> older controls ≥ CADASIL. These changes were not explained by any hippocampal infarct or vascular pathology or glial changes. Our results suggest notable loss of subsets of projection neurons within the hippocampal formation that may contribute to certain memory deficits in CADASIL, which is purely a vascular disease. It is likely that the severe arteriopathy leads to white matter damage which disconnects cortico-cortical and subcortical-cortical networks including the hippocampal formation.

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Hippocampal volume loss was associated with cognitive dysfunction in CADASIL.

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SMI32+ neurons in entorhinal cortex (V) and CA2 regions were reduced in CADASIL.

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Hippocampal cellular changes were not explained by any infarct pathology.

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Neuronal volumes or glial cell numbers per neuron were not changed.

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Selective loss of projection neurons within the hippocampal formation in CADASIL.

MRI of neuronal recovery after low-dose methamphetamine treatment of traumatic brain injury in rats

We assessed the effects of low dose methamphetamine treatment of traumatic brain injury (TBI) in rats by employing MRI, immunohistology, and neurological functional tests. Young male Wistar rats were subjected to TBI using the controlled cortical impact model. The treated rats (n = 10) received an intravenous (iv) bolus dose of 0.42 mg/kg of methamphetamine at eight hours after the TBI followed by continuous iv infusion for 24 hrs. The control rats (n = 10) received the same volume of saline using the same protocol. MRI scans, including T2-weighted imaging (T2WI) and diffusion tensor imaging (DTI), were performed one day prior to TBI, and at 1 and 3 days post TBI, and then weekly for 6 weeks. The lesion volumes of TBI damaged cerebral tissue were demarcated by elevated values in T2 maps and were histologically identified by hematoxylin and eosin (H&E) staining. The fractional anisotropy (FA) values within regions-of-interest (ROI) were measured in FA maps deduced from DTI, and were directly compared with Bielschowsky's silver and Luxol fast blue (BLFB) immunohistological staining. No therapeutic effect on lesion volumes was detected during 6 weeks after TBI. However, treatment significantly increased FA values in the recovery ROI compared with the control group at 5 and 6 weeks after TBI. Myelinated axons histologically measured using BLFB were significantly increased (p<0.001) in the treated group (25.84±1.41%) compared with the control group (17.05±2.95%). Significant correlations were detected between FA and BLFB measures in the recovery ROI (R = 0.54, p<0.02). Methamphetamine treatment significantly reduced modified neurological severity scores from 2 to 6 weeks (p<0.05) and foot-fault errors from 3 days to 6 weeks (p<0.05) after TBI. Thus, the FA data suggest that methamphetamine treatment improves white matter reorganization from 5 to 6 weeks after TBI in rats compared with saline treatment, which may contribute to the observed functional recovery.

Reduction in phosphorylated heavy neurofilament in the cerebellum in HIV disease

In the absence of significant neuronal infection HIV induces neuronal damage and death. The pathogenesis of this process is not clear and can only be assessed in the HIV infected brain by examining surviving neuronal populations. Cerebellar Purkinje cells are a model population. We have already demonstrated glutamate receptor alterations in these neurons in AIDS, and in the current study we have investigated the phosphorylation status of heavy neurofilament (NF-H), which is under the control of various intracellular kinases. While the number of Purkinje cells expressing non-phosphorylated NF-H was unchanged, the number of Purkinje cells expressing phosphorylated NF-H was decreased by 36% in the HIV group. This may be a marker of neuronal damage, and possibly indicate alteration in the activity of various intracellular signalling kinase pathways in the HIV infected brain.

Neurofilament phosphoforms: surrogate markers for axonal injury, degeneration and loss

This review on the role of neurofilaments as surrogate markers for axonal degeneration in neurological diseases provides a brief background to protein synthesis, assembly, function and degeneration. Methodological techniques for quantification are described and a protein nomenclature is proposed. The relevance for recognising anti-neurofilament autoantibodies is noted. Pathological implications are discussed in view of immunocytochemical, cell-culture and genetic findings. With reference to the present symposium on multiple sclerosis, the current literature on body fluid levels of neurofilaments in demyelinating disease is summarised.

Neuroprotective activity of metabotropic glutamate receptor ligands

Metabotropic glutamate receptors form a family of currently eight subtypes (mGluR1-8), subdivided into three groups (I-III). Activation of group-II (mGluR2 and -3) or group-III metabotropic glutamate receptors (mGluR4, -6, -7 and -8) has been established to be neuroprotective in vitro and in vivo. In contrast, group-I mGluRs (mGluR1 and -5) need to be antagonized in order to evoke protection. Initially, all neuroprotective mGluR ligands were analogues of L-glutamate. Those compounds were valuable to demonstrate protection in vitro, but showed limited applicability in animal models, particularly in chronic tests, due to low blood-brain-barrier penetration. Recently, systemically active and more potent and selective ligands became available, e.g., the group-II mGluR agonists LY354740 and LY379268 or group-I antagonists like MPEP (mGluR5-selective) and BAY36-7620 (mGluR1-selective). This new generation of pharmacological agents allows a more stringent assessment of the role of individual mGluR-subtypes or groups of receptors in various nervous system disorders, including ischaemia-induced brain damage, traumatic brain injury, Huntington's and Parkinson's-like pathology or epilepsy. Moreover, the use of genetically modified animals (e.g., knock-out mice) is starting to shed light on specific functions of mGluR-subtypes in experimental neuropathologies.

Preconditioned resistance to oxygen-glucose deprivation-induced cortical neuronal death: alterations in vesicular GABA and glutamate release

Central neurons exposed to several types of sublethal stress, including ischemia, acquire resistance to injury induced by subsequent ischemic insults, a phenomenon called ischemic preconditioning. We modeled this phenomenon in vitro, utilizing exposure to 45 mM KCl to reduce the vulnerability of cultured murine cortical neurons to subsequent oxygen-glucose deprivation. Twenty-four hours after preconditioning, cultures exhibited enhanced depolarization-induced, tetanus toxin-sensitive GABA release and a modest decrease in glutamate release. Total cellular GABA levels were unaltered. Inhibition of GABA degradation with the GABA transaminase inhibitor (+/-)-gamma-vinyl GABA, or addition of low levels of GABA, muscimol, or chlormethiazole to the bathing medium, mimicked the neuroprotective effect of preconditioning against oxygen-glucose deprivation-induced death. However, neuronal death was enhanced by higher levels of these manipulations, as well as by prior selective destruction of GABAergic neurons by kainate. Finally, selective blockade of GABA(A) receptors during oxygen-glucose deprivation or removal of GABAergic neurons eliminated the neuroprotective effects of prior preconditioning. Taken together, these data predict that presynaptic alterations, specifically enhanced GABA release together with reduced glutamate release, may be important mediators of ischemic preconditioning, but suggest caution in regard to interventions aimed at increasing GABA(A) receptor activation.

Metabotropic glutamate receptor subtypes as targets for neuroprotective drugs

Metabotropic glutamate (mGlu) receptors have been considered as potential targets for neuroprotective drugs, but the lack of specific drugs has limited the development of neuroprotective strategies in experimental models of acute or chronic central nervous system (CNS) disorders. The advent of potent and centrally available subtype-selective ligands has overcome this limitation, leading to an extensive investigation of the role of mGlu receptor subtypes in neurodegeneration during the last 2 years. Examples of these drugs are the noncompetitive mGlu1 receptor antagonists, CPCCOEt and BAY-36-7620; the noncompetitive mGlu5 receptor antagonists, 2-methyl-6-(phenylethynyl)pyridine, SIB-1893, and SIB-1757; and the potent mGlu2/3 receptor agonists, LY354740 and LY379268. Pharmacologic blockade of mGlu1 or mGlu5 receptors or pharmacologic activation of mGlu2/3 or mGlu4/7/8 receptors produces neuroprotection in a variety of in vitro or in vivo models. MGlu1 receptor antagonists are promising drugs for the treatment of brain ischemia or for the prophylaxis of neuronal damage induced by synaptic hyperactivity. MGlu5 receptor antagonists may limit neuronal damage induced by a hyperactivity of N-methyl-d-aspartate (NMDA) receptors, because mGlu5 and NMDA receptors are physically and functionally connected in neuronal membranes. A series of observations suggest a potential application of mGlu5 receptor antagonists in chronic neurodegenerative disorders, such as amyotrophic lateral sclerosis and Alzheimer disease. MGlu2/3 receptor agonists inhibit glutamate release, but also promote the synthesis and release of neurotrophic factors in astrocytes. These drugs may therefore have a broad application as neuroprotective agents in a variety of CNS disorders. Finally, mGlu4/7/8 receptor agonists potently inhibit glutamate release and have a potential application in seizure disorders. The advantage of all these drugs with respect to NMDA or AMPA receptor agonists derives from the evidence that mGlu receptors do not "mediate," but rather "modulate" excitatory synaptic transmission. Therefore, it can be expected that mGlu receptor ligands are devoid of the undesirable effects resulting from the inhibition of excitatory synaptic transmission, such as sedation or an impairment of learning and memory.

Glial cells potentiate kainate-induced neuronal death in a motoneuron-enriched spinal coculture system

AMPA/kainate receptor-mediated excitotoxicity is believed to play a pathogenic role in amyotrophic lateral sclerosis. To further characterize the mechanisms involved in AMPA/kainate receptor-mediated motoneuron injury, we investigated the influence of spinal glial cells on kainate-induced motoneuron death in vitro. A motoneuron-enriched neuronal population was obtained from embryonic mouse spinal cord by metrizamide density centrifugation. This population was cultured either on a pre-established glial feeder layer of ventral spinal origin (coculture) or in glia-free conditions (monoculture). Glial feeder layers significantly enhanced basal survival of neurons, and supported neuronal differentiation as judged by neuronal morphology and expression of the motoneuron markers peripherin and SMI-32. Neuronal vulnerability to kainate was two- to three-fold higher in coculture than in monoculture, and increased significantly with time in coculture. The effects of glial feeder layers on neuronal basal survival, differentiation and kainate vulnerability were not mimicked by conditioned medium from glial cells. The increase in neuronal kainate vulnerability with time in coculture was associated with a marked rise in the proportion of cocultured neurons possessing Ca2+-permeable AMPA/kainate receptors, as determined by kainate-activated Co2+-uptake. Neurons in monoculture were unstained by kainate-activated Co2+-uptake. Neurons were immunoreactive to specific antibodies against the AMPA receptor subunits GluR1 and GluR2 both in monoculture and coculture. This study indicates that motoneuron differentiation in coculture is associated with increased vulnerability to kainate and increased expression of Ca2+-permeable AMPA/kainate receptors. In this paradigm glial cells support basal survival and differentiation of neurons, but potentiate kainate-induced neuronal death.

Investigations of non-NMDA receptor-induced toxicity in serum-free antioxidant-rich primary cultures of murine cerebellar granule cells

A culture system was developed whereby murine cerebellar granule cells were grown under serum-free conditions in chemically defined B27-supplemented neurobasal medium plus depolarizing K+ levels, to allow the investigation of the role of agonists at the kainate and alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) receptors in glutamate-mediated neurotoxicity. Neurones were killed in a concentration-dependent manner by L-glutamate, kainate and its analogues, domoate and 4-(2-methoxyphenyl)-2-carboxy-3-pyrrolidineacetic acid, but not by (S)-AMPA or (S)-5-fluorowillardiine. Kainate (60% maximal cell death at 1mM) was markedly more toxic than NMDA (40% maximal cell death at 1mM) and was shown to be the predominant cause of excitatory amino acid-induced toxicity in these cells as the neuronal death induced by KA was attenuated by the non-NMDA antagonist CNQX, but not the AMPA antagonist LY293558. This study suggests that serum-free cultures of cerebellar granule cells in B27-supplemented neurobasal medium provide a valuable model system for investigations of the role of the kainate receptor in excitatory amino acid-induced neurodegeneration.

Ca2+-independent excitotoxic neurodegeneration in isolated retina, an intact neural net: a role for Cl- and inhibitory transmitters

Rapidly triggered excitotoxic cell death is widely thought to be due to excessive influx of extracellular Ca2+, primarily through the N-methyl-D-aspartate subtype of glutamate receptor. By devising conditions that permit the maintenance of isolated retina in the absence of Ca2+, it has become technically feasible to test the dependence of excitotoxic neurodegeneration in this intact neural system on extracellular Ca2+. Using biochemical, Ca2+ imaging, and electrophysiological techniques, we found that (1) rapidly triggered excitotoxic cell death in this system occurs independently of both extracellular Ca2+ and increases in intracellular Ca2+; (2) this cell death is highly dependent on extracellular Cl-; and (3) lethal Cl- entry occurs by multiple paths, but a significant fraction occurs through pathologically activated gamma-aminobutyric acid and glycine receptors. These results emphasize the importance of Ca2+-independent mechanisms and the role that local transmitter circuitry plays in excitotoxic cell death.

Kainate-stimulated Zn2+ uptake labels cortical neurons with Ca2+-permeable AMPA/kainate channels

The endogenous cation, Zn2+, is synaptically released and may trigger neurodegeneration after permeating through NMDA channels, voltage sensitive Ca2+ channels (VSCC), or Ca2+ permeable AMPA/kainate channels (Ca-A/K). Neurons expressing Ca-A/K can be identified by a histochemical stain based upon kainate-stimulated Co2+ uptake (Co2+(+) neurons). The primary objective of this study was to determine whether a similar approach could be employed to visualize agonist-stimulated intracellular Zn2+ accumulation, and, thus, to test the hypothesis that Ca-A/K permit particularly rapid Zn2+ flux. Substituting Zn2+ for Co2+ during agonist-stimulated uptake, followed by Timm's sulfide-silver staining to visualize intracellular Zn2+, resulted in distinct labeling of a subpopulation of cortical neurons (Zn2+(+) neurons) closely resembling Co2+(+) neurons, suggesting that, like Co2+, Zn2+ may permeate Ca-A/K with particular rapidity. Neither NMDA nor high K+ triggered comparable Zn2+ accumulation, indicating substantially greater permeation through Ca-A/K than through NMDA channels or VSCC. Both fluorescence studies of intracellular Zn2+ accumulation and double staining studies (using SMI-32 and anti-glutamate decarboxylase antibodies, both markers of cortical neuronal subsets), support the contention that Zn2+ and Co2+ labeling identify a common set of neurons characterized by expression of AMPA/kainate channels directly permeable to Zn2+ and Co2+ as well as Ca2+. Furthermore, the preferential destruction of Zn2+(+) neurons (like Co2+(+) neurons) after brief kainate exposures in the presence of lower, more physiologic concentrations of Zn2+ suggests that Zn2+ permeation through Ca-A/K could contribute to selective neurodegeneration in disease. Finally, the study provides a novel and potentially advantageous histochemical approach for kainate-stimulated Co2+ or Zn2+ uptake labeling, using a room temperature technique (Timm's staining) rather than the usual hot AgNO3 development of the Co2+ stain.

Significant loss of pyramidal neurons in the angular gyrus of patients with Huntington's disease

The primary site of pathology in Huntington's disease (HD) is the caudate nucleus. However, cortical changes are also commonly reported. While many researchers have studied pathology in the frontal lobe, little attention has been paid to posterior cortical regions. The aim of this study is to examine pathology in the parietal lobe in patients with HD as it has specific projections to the caudate nucleus. Post-mortem brain tissue was obtained from HD patients with both a positive family history and clinicopathological diagnosis (n = 6; Vonsattel grades 2-4) as well as from neurologically normal controls (n = 6). The angular gyrus of the parietal lobe was sampled and cellular quantification of SMI-32 immunohistochemically detected pyramidal neurons performed. Cortical blocks were sectioned at 50 microns on a cryostat and stained immunohistochemically using antigen retrieval methods and peroxidase visualization. HD subjects had noticeable histological changes including smaller neurons and a disruption of cortical laminar pattern. Quantification using a point counting method to find the areal fraction of immunoreactive neurons revealed a severe loss of pyramidal neurons in the angular gyrus of HD subjects compared with controls (reduced on average to 55% of mean control values, P = 0.038 using the Mann-Whitney U-test). This striking cortical pathology suggests that HD may preferentially target posterior cortical regions, particularly the angular gyrus which has a significant projection to the caudate nucleus in primates.

Phosphorylated neurofilament expression and resistance to kainate toxicity

Antibodies directed against phosphorylated neurofilaments, which are major proteins of the neuronal cytoskeleton, usually do not label neuronal cell bodies except in some neurological diseases. In the present study, we show that in rat cortical cell cultures exposed to kainate there is an inverse relation between neuronal survival and the proportion of neuronal cell bodies stained by a monoclonal antibody (clone SMI31) that recognizes extensively phosphorylated neurofilament proteins (150 kDa and 200 kDa). The immunoblot analysis also revealed an increase in 150-kDa phosphorylated neurofilament expression in kainate-treated cell cultures. Furthermore, the direct quantification of viable neurons SMI31-immunopositive or immunonegative in perikarya showed that the majority of neurons resistant to kainate toxicity expressed phosphorylated neurofilaments in their cell bodies. The percentage of viable neurons displaying SMI31-immunoreactivity in their cell bodies increased from 14.7% in control cultures to 30.0% in cultures treated with 10 microM kainate. These data suggest that phosphorylated neurofilament expression is associated with a reduced cell vulnerability to excitotoxicity induced by kainate.