In vivo toxicity of prion protein in murine scrapie: ultrastructural and immunogold studies

Prion protein (PrP) is a cell surface, host coded, sialoglycoprotein which accumulates in excess in scrapie, Creutzfeldt‐Jakob disease, bovine spongiform encephalopathy and other transmissible spongiform encephalopathies. Infection of mice with the 87 V or ME7 scrapie strains results in distinctive and very different light microscopical patterns of vacuolation and disease specific PrP accumulation. In both of these scrapie strains immunogold electron microscopy was used to locate PrP to the plasmalemma of neurons from where it was released into the neuropil. Initial PrP accumulation around neurons and in early plaques lacking amyloid fibrils was generally not associated with morphological changes either of the neuron or dendrite releasing the PrP or in the adjacent neuropil in which excess PrP accumulated. However, accumulation of pre‐amyloid PrP in some brain areas was associated with specific degeneration of dendritic spines and axon terminals. Initial PrP aggregation into fibrils was also associated with tissue damage with both ME7 and 87 V plaques and diffuse accumulations. Tissue damage associated with fibrillogenesis was localized and would not be expected to have clinical significance. We conclude that pre‐amyloid PrP release and accumulation is not invariably toxic, either to the neuron releasing PrP or to the neuropil into which it is released. However, axon terminal degeneration and dendritic spine loss in some neuroanatomical areas may be indicative of specific PrP toxicity and may be the main cause of neurological dysfunction in murine scrapie.     

Enhanced expression of TNF-R1 protein in NMDA-mediated cell death in the retina

Multiple apoptosis-related genes are expressed in the retina after exposure to N-methyl-D-aspartic acid (NMDA). For example, the mRNAs for TNF-R1, FasL, and Nur77 are up-regulated between 2.8 and 7-fold [Mol. Brain Res. 91 (2001) 34-42]. The purpose of the present study is to examine prospective changes in protein expression for these genes and to determine their cellular localizations subsequent to NMDA stimulation. Following anesthesia, a single intravitreal injection of 4 mM NMDA was administered into the right eye of anesthetized rats. The left eye was injected with phosphate-buffered saline. Retinae were harvested at 2 and 24 h postinjection. Western-blot and immunocytochemical techniques were used to detect changes in protein expression levels, and to localize their distributions within the retina. Analyses of Western blots demonstrated a significant increase in TNF-R1 (100 and 80%) compared to the sham-controls at 2 and 24 h postinjection with NMDA. Immunolabeling of TNF-R1 was observed in the inner nuclear layer (INL) at 2 h postinjection with NMDA. TNF-R1 was also clearly evident in cells within the INL and ganglion cell layers (GCL) at 24 h post-injection with NMDA. In contrast to these changes in TNF-R1 there were no significant changes in the levels or distributions of FasL or Nur77 in NMDA-stimulated animals at either 2 or 24 h when compared to the sham-controls. These results implicate the TNF-R1 signal transduction pathway in NMDA-induced cell death in the INL and GCL of the retina.     

Characterization of the microglial response in murine scrapie

The nature of the glial and inflammatory cell responses to infection in scrapie–affected brains was studied in terminally–affected mice of Ave scrapie models. There were marked astrocytic and microglial responses. Microglia showed increased staining of the surface antigens F4/80, leucocyte–common antigen, type 3 complement receptor, and elevated endocytotic and lysosomal activity. In all models, the astrocytic and microglial responses were largely restricted to anatomical regions of the brain showing vacuolation and/or plaque formation and pathological accumulations of PrP. Expression of MHC Class II was patchy and present on microglia in the neuropil of areas with the most intense microglial activation and on occasional perivascular macrophages. This microglial response may represent a modified form of inflammatory response.     

Caspase and calpain substrates: roles in synaptic plasticity and cell death.

Neurons are an unusual type of cell in that they send processes (axons and dendrites) over great distances. This elaborate morphology, together with their excitability, places neurons at risk for multiple insults. Recent studies have demonstrated that apoptotic and excitotoxic mechanisms not only contribute to neuronal death, but also to synaptic dysfunction and a breakdown in neural circuitry (see Mattson and Duan [1999] J. Neurosci. Res. 58:152-166, this issue). Proteases of the caspase and calpain families have been implicated in neurodegenerative processes, as their activation can be triggered by calcium influx and oxidative stress. Caspases and calpains are cysteine proteases that require proteolytic cleavage for activation. The substrates cleaved by caspases include cytoskeletal and associated proteins, kinases, members of the Bcl-2 family of apoptosis-related proteins, presenilins and amyloid precursor protein, and DNA-modulating enzymes. Calpain substrates include cytoskeletal and associated proteins, kinases and phosphatases, membrane receptors and transporters, and steroid receptors. Many of the substrates of caspases and calpains are localized in pre- and/or postsynaptic compartments of neurons. Emerging data suggest that, in addition to their roles in neurodegenerative processes, caspases and calpains play important roles in modulating synaptic plasticity. The present article provides a review of the properties of the different caspases and calpains, their roles in cell death pathways, and the substrates upon which they act. Emerging data are considered that suggest key roles for these proteases in the regulation of synaptic plasticity.     

Abnormal synaptic plasticity and impaired cognition in schizophrenia

Schizophrenia (SCZ) is a severe mental illness that affects several brain domains with relation to cognition and behaviour. SCZ symptoms are typically classified into three categories, namely, positive, negative, and cognitive. The etiology of SCZ is thought to be multifactorial and poorly understood. Accumulating evidence has indicated abnormal synaptic plasticity and cognitive impairments in SCZ. Synaptic plasticity is thought to be induced at appropriate synapses during memory formation and has a critical role in the cognitive symptoms of SCZ. Many factors, including synaptic structure changes, aberrant expression of plasticity-related genes, and abnormal synaptic transmission, may influence synaptic plasticity and play vital roles in SCZ. In this article, we briefly summarize the morphology of the synapse, the neurobiology of synaptic plasticity, and the role of synaptic plasticity, and review potential mechanisms underlying abnormal synaptic plasticity in SCZ. These abnormalities involve dendritic spines, postsynaptic density, and long-term potentiation-like plasticity. We also focus on cognitive dysfunction, which reflects impaired connectivity in SCZ. Additionally, the potential targets for the treatment of SCZ are discussed in this article. Therefore, understanding abnormal synaptic plasticity and impaired cognition in SCZ has an essential role in drug therapy.     

Morphogenesis of amyloid plaques in 87V murine scrapie†

Amyloid plaques of scrapie–infected mouse brains are composed of fibrillar forms of a host coded, cell surface sialoglycoprotein called PrP (prion protein). Serial ultrastructural immunogold staining was performed on plaques identified by light microscopic immunocytochemistry of brains of VM mice infected with the 8 7V strain of scrapie. Classical plaques, of a kuru–type morphology, were composed of a central core of bundles of amyloid fibrils. Amyloid fibrils of classical plaques were immunoreactive for PrP. In addition, PrP was also found at the plaque periphery, in the absence of fibrils, at the plasmalemma of cell processes and in the associated extracellular spaces. Frequent microglial cells and occasional astrocytes contained PrP within lysosomes. Other plaques with few or no recognizable amyloid fibrils were frequent and were termed primitive plaques. PrP could be demonstrated in a non–fibrillar form at the plasmalemma and in the extracellular spaces between neurites of such plaques. Many primitive plaques showed little or no sub–cellular pathology associated with the PrP accumulation. PrP was closely associated with the plasma–lemma of occasional dendrites passing towards the centre of primitive plaques. These results suggest that plaques are formed around one or more PrP releasing dendrites. PrP accumulates in the extracellular spaces adjacent to such processes prior to its spontaneous aggregation into fibrils. Lysosomal accumulation of PrP in microglia and astrocytes located at the periphery of plaques suggest that these cells are involved in the phagocytosis of excess or abnormal PrP.     

Astrocytes accumulate 4-hydroxynonenal adducts in murine scrapie and human Creutzfeldt-Jakob disease

Scrapie-infected mice are considered a model for study in prion diseases, which are characterized by the progressive accumulation in the brain of an abnormal isoform (PrPsc) of the normal cellular prion protein (PrPc). Increasing data suggest that the neurodegenerative process in prion diseases may result, at least partially, from a defect in antioxidant function, but so far in vivo oxidative stress remains poorly documented. We report here that 4-hydroxynonenal, a lipid peroxidation by-product, forms protein adducts in brains of scrapie-infected mice and of Creutzfeldt-Jakob disease affected patients. In scrapie mice, studies on the progression of PrPsc accumulation, glial activation, ubiquitin deposition, and 4-HNE adduct formation allowed us to conclude the late occurrence of oxidative damage in the course of the disease. Massive 4-HNE accumulation was identified in astrocytes, but not in neurons or microglial cells. These findings suggest an important oxidative stress (and subsequent lipid peroxidation) in astrocytes, with possible consequences on their neuronal trophic function.     

Temporal expression of AMP-activated protein kinase activation during the kainic acid-induced hippocampal cell death

Kainic acid (KA)-induced seizure induces the hippocampal cell death. There are reports that AMP-activated protein kinase (AMPK), which is an important regulator of energy homeostasis of cells, has been proposed as apoptotic molecule. In this study, we investigated the altered expression of AMPK cascade in the hippocampus of mice during KA-induced hippocampal cell death. Mice were killed at 2, 6, 24 or 48 h after KA (30 mg/kg) injection. Histological evaluation of KA-treated hippocampus revealed hippocampal cell death first at 6 h and appearing prominently by 48 h after KA injection. Immunoreactivity of Ca²⁺/calmodulin-dependent protein kinase kinaseβ (CaMKKβ) was increased after KA treatment. In Western blot analysis, AMPK activation was increased 2 h after KA treatment. The proteins of downstream AMPK, including those of glucose transporter1 (GLUT1) and phosphorylation of Acetyl CoA Carboxylase (ACC) were increased in the hippocampus after KA treatment. These results indicate that sustained AMPK activation might be a mechanism by which KA-induced seizure causes hippocampal cell death of mice.     

A novel hamster prion protein mRNA contains an extra exon: increased expression in scrapie

Prion protein (PrP) is the only known constituent of the agents (called prions) that cause fatal neurodegenerative diseases in animals and humans. PrP derives from a host protein encoded by a single copy gene having three known exons in mice, cattle and sheep but only two exons in hamsters and humans. We have identified and sequenced the missing exon from the hamster PrP gene. The new hamster PrP exon is 83% identical to mouse exon 2 and 76% identical to exon 2 from cattle and sheep. PrP mRNAs containing the new exon 2 (mRNA^[1+2+3]) were expressed in the colliculi, frontal cortex and hippocampus of normal hamsters at ∼30% to ∼50% of the levels of the mRNA without exon 2 (mRNA^[1+3]). Expression of PrP mRNA^[1+2+3] was increased in the colliculi beginning 49 days after inoculation with scrapie prions and reached a level 2.5 times normal by day 77. Increased expression of PrP mRNA^[1+2+3] in the colliculi correlated with expression of glial fibrillary acidic protein (GFAP) mRNA. Expression of GFAP and PrP mRNAs was not significantly increased in the hippocampus or the frontal cortex during the disease. Our study shows that exon 2 plays a role in regulating the cellular expression of hamster PrP and suggests that mRNA^[1+2+3] may be preferentially expressed in hamster astrocytes. © 1997 Elsevier Science B.V. All rights reserved.     

Tubulovesicular particles occur early in the incubation period of murine scrapie

Tubulovesicular bodies are structures, apparently specific to the transmissible spongiform encephalopathies, which are of unknown composition and significance. Prion protein (PrP) is absent from tubulovesicular bodies when tissues are examined by immunogold electron microscopy. In the F1 cross of C57 and VM mice (CVF1) infected with ME7 scrapie there is a marked degeneration of hippocampal CA1 neurons. In this model the earliest changes seen, at about 100 days post inoculation (dpi) are a degeneration of axon terminals and synaptic loss. Terminal disease is around 250 dpi. In blind coded trials we counted the number of tubulovesicular particles and estimated their density in 56–76 electron micrographs taken from the stratum radiatum of each of one or two CVF1 ME7-infected mice at 84, 100, 126, 154 and 181 dpi and from four normal brain inoculated control mice. Tubulovesicular particles were present from 98 dpi and the density of particles increased with increasing incubation period. The very early occurrence of tubulovesicular particles, before the presence of significant pathology, argues that tubulovesicular particles are a part of the primary disease and are not epiphenomena. Received: 28 June 1999 / Revised: 30 August 1999 / Accepted: 6 September 1999     

Early induction of protein nexin-I in scrapie.

We used RNA fingerprinting by arbitrary primed PCR to identify genes whose expression is up-regulated in the brain of hamsters affected by prion disease. One gene implicated by RNA fingerprinting encoded the hamster homologue of protein nexin-I (PN-I), a serine proteinase inhibitor, and was further investigated by Northern blot analysis. PN-I mRNA levels were increased at pre-clinical stages (19 days after inoculation) and remained elevated when the spongiform encephalopathy was anatomopathologically and clinically evident (at 50 and 80 days). Future RNA screening conducted as illustrated may help to reveal a spectrum of genes relevant for the etiopathogenesis and/or diagnosis of prion disease.     

Differential synaptic vesicle protein expression in the barrel field of developing cortex

The distribution of four proteins associated with synaptic vesicles, SV2, synaptophysin, synapsin I, and rab3a, was investigated during postnatal development of the posteromedial barrel subfield (PMBSF) in the rat somatosensory cortex. A distinct progression in the appearance of the different synaptic vesicle proteins within the PMBSF was observed. SV2, synapsin I, and synaptophysin revealed the organization of the barrel field in the neonate. This early demarcation of the cortical representation of the vibrissal array coincides with the earliest known age for the emergence of the cytoarchitectonic organization of this region. In contrast, rab3a did not delimit the barrels until the end of the 1st postnatal week, coincident with the known onset of adult-like physiological activity and the loss of plasticity in afferents to this region. In addition, the appearance of the different synaptic vesicle proteins occurred earlier within the PMBSF than in the adjacent extra-barrel regions of the cortex. These results show that the molecular differentiation of synaptic fields across the cortex is not a homogeneous and synchronous process in terms of synaptic vesicle protein expression. Because these proteins act together in mature synapses to ensure the regulated release of neurotransmitters, our results suggest that this temporo-spatial asynchrony may underlie different potentials for synaptic activity and thus contribute to the development of cortical maps. © 1996 Wiley-Liss, Inc.     

Abnormal plasticity in dystonia: Disruption of synaptic homeostasis

Work over the past two decades lead to substantial changes in our understanding of dystonia, which was, until recently, considered an exclusively sporadic movement disorder. The discovery of several gene mutations responsible for many inherited forms of dystonia has prompted much effort in the generation of transgenic mouse models bearing mutations found in patients. The large majority of these rodent models do not exhibit overt phenotypic abnormalities, or neuronal loss in specific brain areas. Nevertheless, both subtle motor abnormalities and significant alterations of synaptic plasticity have been recorded in mice, suggestive of an altered basal ganglia circuitry. In addition, robust evidence from experimental and clinical work supports the assumption that dystonia may indeed be considered a disorder linked to the disruption of synaptic "scaling", with a prevailing facilitation of synaptic potentiation, together with the loss of synaptic inhibitory processes. Notably, neurophysiological studies from patients carrying gene mutations as well as from non-manifesting carriers have shown the presence of synaptic plasticity abnormalities, indicating the presence of specific endophenotypic traits in carriers of the gene mutation. In this survey, we review findings from a broad range of data, obtained both from animal models and human research, and propose that the abnormalities of synaptic plasticity described in mice and humans may be considered an endophenotype to dystonia, and a valid and powerful tool to investigate the pathogenic mechanisms underlying this movement disorder. This article is part of a Special Issue entitled "Advances in dystonia".     

Experience-dependent regulation of functional maps and synaptic protein expression in the cat visual cortex

Although the basis of our knowledge of experience-dependent plasticity comes from studies on carnivores and primates, studies examining the physiological and molecular mechanisms that underlie development and plasticity have increasingly employed mice. We have used several common rearing paradigms, such as dark-rearing and monocular deprivation (MD), to examine the timing of the physiological and molecular changes to altered experience in the cat primary visual cortex. Dark-rearing from birth or for 1 week starting at 4 weeks of age produced a similar reduction in the amplitude of responses measured through intrinsic signal imaging and a reduction in orientation selectivity. One week of visual experience following dark-rearing until 4 weeks of age yielded normal responses in both amplitude and orientation selectivity. The depression of deprived-eye responses was similar in magnitude after 2 and 7 days of MD. In contrast, non-deprived-eye responses almost doubled in magnitude after 7 days compared with 2 days of MD. These changes in the functional properties of primary visual cortex neurons were mirrored by specific changes in synaptic protein expression. Changes in proteins such as the NR2A and NR2B subunits of the N-methyl-D-aspartate receptor, postsynaptic density protein 95, alpha-CA(2+) /calmodulin-dependent protein kinase II (αCaMKII), and GABA(A) α1a indicated that the levels of sensory activity regulated mechanisms associated with both excitatory (NR2A and NR2B) and inhibitory (GABA(A) α1a) transmission so as to maintain response homeostasis. Additionally, we found that MD regulated the AMPA receptor glutamate (GluR1) subunit as well as signalling molecules (αCaMKII and synaptic Ras GTPase activating protein, SynGAP) downstream of N-methyl-D-aspartate receptors. Proteins in a common signalling pathway appeared to have similar developmental expression profiles that were broadly similar between cats and rodents.     

Early loss of dendritic spines in murine scrapie revealed by confocal analysis

Confocal analysis of dye-filled neurons has revealed a significant early loss of dendritic spines in a murine scrapie model in which neuron loss occurs in the hippocampus. An 18% loss of spines was found at 109 days, > 50 days before neuron loss occurs, and by 126 days a 51% spine loss was found. Spine loss is concurrent with synapse loss, axon terminal degeneration and a decrease in long term potentiation in this model. Preceding these changes is the deposition of disease specific PrP at 70 days, which may initiate the damage to dendritic spines and the subsequent degeneration of synapses. We suggest that these changes underlie the development of clinical disease in the transmissible spongiform encephalopathies.     

Creatine protects against 3-nitropropionic acid-induced cell death in murine corticostriatal slice cultures

In murine corticostriatal slice cultures, we studied the protective effects of the bioenergetic compound creatine on neuronal cell death induced by the mitochondrial toxin 3-nitropropionic acid (3-NP). 3-NP caused a dose-dependent neuronal degeneration accompanied by an increased lactate dehydrogenase (LDH) activity in the cell culture medium. An increased ratio of lactate to pyruvate concentration in the medium suggested that metabolic activity shifted to anaerobic energy metabolism. These effects were predominantly observed in the 24-h recovery period after 3-NP exposure. Creatine protected against 3-NP neurotoxicity: LDH activity was reduced and aerobic respiration of pyruvate was stimulated, which resulted in lower lactate levels and less cell death. In both striatum and cortex, apoptosis in 3-NP-exposed slices was demonstrated by increased activation of the pro-apoptotic protein caspase-3 and by numerous cells exhibiting DNA fragmentation detected by the terminal transferase-mediated biotinylated-UTP nick end-labeling (TUNEL) technique. Creatine administration to the 3-NP-exposed corticostriatal slices resulted in a reduced number of TUNEL-positive cells in the recovery period. However, in the striatum, an unexpected increase of both TUNEL-positive cells and caspase-3-immunostained cells was observed in the exposure phase in the presence of creatine. In the recovery phase, caspase-3-immunostaining decreased to basal levels in both striatum and cortex. These findings suggest that 3-NP-induced neuronal degeneration in corticostriatal slices results from apoptosis that in the cortex can be prevented by creatine, while in the more vulnerable striatal cells it may lead to an accelerated and increased execution of apoptotic cell death, preventing further necrosis-related damage in this region.     

Modifications of tau protein during neuronal cell death

Accumulation of hyperphosphorylated tau protein and progressive neuronal loss are among the major hallmarks of certain neurodegenerative disorders including Alzheimer's disease. However, the relationship between tau phosphorylation and neuronal cell death remains unclear. Here we have analyzed tau modifications during two forms of neuronal death, apoptosis and necrosis, using primary cultures of cerebellar granule neurons as a simple model system. Induction of neuronal apoptosis by inhibition of phosphatidylinositol 3-kinase results in a rapid increase in the phosphorylation of tau, which is followed by the dephosphorylation and cleavage of the protein. In contrast, necrosis triggered by high salt shock or glutamate treatment leads to a rapid dephosphorylation and an almost complete proteolysis of tau. These data suggests that a transient tau hyperphosphorylation occurs at an early stage of apoptosis, whereas tau is dephosphorylated and cleaved during the late phase of apoptosis as well as in necrotic neurons.