Prion diseases are characterized by accumulation of misfolded prion protein (PrP Sc ), and neuronal death by apoptosis. Here we show that nanomolar concentrations of puri®ed PrP Sc from mouse scrapie brain induce apoptosis of N2A neuroblastoma cells. PrP Sc toxicity was associated with an increase of intracellular calcium released from endoplasmic reticulum (ER) and up-regulation of several ER chaperones. Caspase-12 activation was detected in cells treated with PrP Sc , and cellular death was inhibited by overexpression of a catalytic mutant of caspase-12 or an ER-targeted Bcl-2 chimeric protein.Scrapie-infected N2A cells were more susceptible to ER-stress and to PrP Sc toxicity than non-infected cells. In scrapie-infected mice a correlation between caspase-12 activation and neuronal loss was observed in histological and biochemical analyses of different brain areas. The extent of prion replication was closely correlated with the up-regulation of ER-stress chaperone proteins. Similar results were observed in humans affected with sporadic and variant Creutzfeldt±Jakob disease, implicating for the ®rst time the caspase-12 dependent pathway in a neurodegenerative disease in vivo, and thus offering novel potential targets for the treatment of prion disorders.
Prion diseases are transmissible neurodegenerative disorders characterized by extensive neuronal apoptosis and accumulation of misfolded prion protein (PrP SC). Recent reports indicate that PrP SC induces neuronal apoptosis via activation of the endoplasmic reticulum (ER) stress pathway and activation of the ER resident caspase-12. Here, we investigate the relationship between prion replication and induction of ER stress during different stages of the disease in a murine scrapie model. The first alteration observed consists of the upregulation of the ER chaperone of the glucose-regulated protein Grp58, which was detected during the presymptomatic phase and followed closely the formation of PrP SC . An increase in Grp58 expression correlated with PrP SC accumulation at all stages of the disease in different brain areas, suggesting that this chaperone may play an important role in the cellular response to prion infection. Indeed, in vitro studies using N2a neuroblastoma cells demonstrated that inhibition of Grp58 expression with small interfering RNA led to a significant enhancement of PrP SC toxicity. Conversely, overexpression of Grp58 protected cells against PrP SC toxicity and decreased the rate of caspase-12 activation. Grp58 and PrP were shown to interact by coimmunoprecipitation, observing a higher interaction in cells infected with scrapie prions. Our data indicate that expression of Grp58 is an early cellular response to prion replication, acting as a neuroprotective factor against prion neurotoxicity. Our findings suggest that targeting Grp58 interaction may have applications for developing novel strategies for treatment and early diagnosis of prion diseases.
The main event in the pathogenesis of prion diseases is the conversion of the cellular prion protein (PrPTransmissible spongiform encephalopathies or prion diseases are a group of infectious neurodegenerative diseases that affect several species, including humans.
A non-nuclear isoform of histone H1 is constitutively expressed in neurones. This protein is the major lipopolysaccharide (LPS)-binding protein in the brain. Since the major systemic LPS-binding protein is released in the liver and is an acute phase reactant, we were interested to learn whether this novel CNS histone showed altered expression following neuronal injury. We have therefore examined the changes in the expression of this molecule in acute neuronal injury and in two neurodegenerative pathologies, murine scrapie and Alzheimer's disease. No upregulation or change in H1 staining was observed in acute neurodegeneration induced by the intrastriatal injection of the glutamate antagonist N-methyl d-aspartic acid. In contrast, Western blotting indicated that histone H1 is upregulated in the brains of mice with clinical signs of scrapie. Immunohistochemistry revealed that in the regions of pathology there was increased staining for histone H1 in the neurones and the surrounding neuropil. Cells with an astrocytic appearance were also seen to stain positively for H1 but only in the regions of pathology. Immunofluorescent double staining for glial fibrillary acid protein (GFAP) and histone H1 confirmed that these cells were indeed astrocytes. Alzheimer's disease brain also showed an increase in the neuronal and astrocytic staining but only in regions of pathology. The function of histone in the CNS is unknown but the data presented here demonstrate an upregulation in areas of neuronal degeneration, which indicates that it may be involved in disease pathogenesis.
The early responses of cat retinal ganglion cells to axotomy have been examined using neurofibrillar and Nissl-stained wholemounts. We were interested to learn whether the enhanced neurofilament expression, seen in a number of neuronal systems, was also present in different neuronal populations of the cat retina and could be used to study the distribution of these cells. We found that beta ganglion cells degenerate very rapidly after axotomy with the nuclei becoming pyknotic within a few days. Few beta cells showed increased neurofibrillar staining of the dendrites. The cell body degenerated prior to any visible degenerative changes in the axon. A proportion of the alpha and gamma ganglion cells degenerated in the first two to three weeks after axotomy. The alpha cells underwent markedly enhanced neurofibrillar staining of their dendrites prior to degeneration. The Nissl material of the cell bodies diminished as the cells degenerated but we have not observed pyknotic nuclei. The dendritic trees of some axotomised gamma cells were also revealed by the neurofibrillar stain three weeks after axotomy. These results show that retinal ganglion cells do not degenerate by a dying back process. We suggest that the rapid degeneration of the beta ganglion cell population comes about by excitotoxic cell death, a consequence of their large glutamatergic input from bipolar cells. The degenerating beta ganglion cells have the morphological appearance of cells undergoing apoptosis.
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