Project description:While prion infections have been extensively characterized in the laboratory mouse, little is known regarding the molecular responses to prions in other rodents. To explore these responses and make comparisons, we generated a prion disease in the laboratory rat by successive passage of mouse RML prions. Here we describe the accumulation of prions and associated pathology in the rat and describe the transcriptional impact throughout prion disease. Comparative transcriptional profiling between laboratory mice and rats suggests that similar molecular processes are unfolding in response to prion infection. At the level of individual transcripts, however, variability exists between mice and rats and many genes deregulated in mouse scrapie are not affected in rats. Notwithstanding these differences, many transcriptome responses are conserved between mice and rats infected with scrapie. Our findings highlight the usefulness of comparative approaches to understanding neurodegeneration and prion diseases in particular.

Project description:While prion infections have been extensively characterized in the laboratory mouse, little is known regarding the molecular responses to prions in other rodents. To explore these responses and make comparisons, we generated a prion disease in the laboratory rat by successive passage of mouse RML prions. Here we describe the accumulation of prions and associated pathology in the rat and describe the transcriptional impact throughout prion disease. Comparative transcriptional profiling between laboratory mice and rats suggests that similar molecular processes are unfolding in response to prion infection. At the level of individual transcripts, however, variability exists between mice and rats and many genes deregulated in mouse scrapie are not affected in rats. Notwithstanding these differences, many transcriptome responses are conserved between mice and rats infected with scrapie. Our findings highlight the usefulness of comparative approaches to understanding neurodegeneration and prion diseases in particular. We Adapted RML Mouse Scrapie into Rats and measured the resulting gene expression changes in brain as a result of disease progression. Rats were infected by intracranial inoculation with prion isolates obtained by adaptation of mouse RML scrapie prions into rats. Brain samples were collected from third and fourth passage infected rats and age-matched controls at specified timepoints and gene expression profiles obtained. For each time point, 3 diseased and control brain samples were profiled.

Project description:Synapse dysfunction and synaptic loss are a central feature of neurodegenerative disorders, including prion disease. The cellular prion protein (PrPC) binds prion, amyloid-β, tau, and α-synuclein oligomers, resulting in the activation of macromolecular complexes and signaling at the post-synapse, yet the initial signaling events are unclear. Here we used a transcriptomic approach focused on the early-stage, prion-infected hippocampus of male wild type mice, and identify immediate early genes, including the synaptic activity response gene, Arc/Arg3.1, as significantly upregulated. In a longitudinal study of the prion-infected hippocampus, Arc/Arg-3.1 protein increased, from early to terminal disease. Notably, metabotropic glutamate receptor levels (mGluR5 dimers) were markedly reduced over time, while phosphorylated AMPA receptors (pGluA1-S845) levels increased. Sporadic Creutzfeldt-Jakob disease (sCJD) post-mortem cortical samples also showed low levels of mGluR5 dimers. Together, these findings suggest that prions trigger a chronic Arc response, an increase in phosphorylated GluA1, and a reduction in mGluR5 receptors beginning in early disease.

Project description:An essential and remarkable process of the biochemical and physiological features in prion diseases is the conversion of a host-encoded prion protein (PrPC) into a misfolded isoform (PrPSc). The conversion of PrPC and the replication of prions, in cases of peripheral infection, occur following the uptake and subsequent spread of prions to brain via spinal cord. We investigated the changes of gene expression profiles in the spleen, cervical spinal cord and thalamus following intraperitoneal inoculation of ME7 scrapie prion and the inter-tissue alterations of the differentially expressed genes through Venn diagram to find genes which are commonly influenced by ME7 scrapie prion spread in the three tissues.

Project description:Prions are self-propagating protein aggregates that act as protein-based genetic elements in fungi. Although prevalent in eukaryotes, prions have not been identified in bacteria. Here we demonstrate that a bacterial protein, transcription terminator Rho of Clostridium botulinum (Cb-Rho), can form a prion. Specifically, we identify a candidate prion-forming domain (cPrD) in Cb-Rho and show that it confers amyloidogenicity on Cb-Rho and can functionally replace the PrD of a yeast prion-forming protein. Furthermore, we show that its cPrD enables Cb-Rho to access alternative conformations in bacteria, a soluble form that terminates transcription efficiently and an aggregated, self-propagating prion form that is functionally compromised, causing genome-wide changes in the transcriptome. Thus, Cb-Rho functions as a protein-based genetic element in bacteria, suggesting that the emergence of prions predates the evolutionary split between eukaryotes and bacteria.

Project description:Cultured organotypic cerebellar slices were exposed for different time points with either prions (RML) versus non-infectious brain homogenate (NBH) or ligands to the globular domain of the prion protein (POM1) vs IgG We used microarrays to characterize the temporal response of two inducers prion protein dependent cell death: COCS were exposed to RML prions or Non-infectious brain homogenate (NBH) and harvested after 14d, 25d, 38d and 45d (4 replicates each condition). COCS were exposed to POM1 or IgG and harvested after 8h, 1d, 3d, 7d, 10d (4 replicates each condition).

Project description:Cell culture models allow prion propagation studies ex vivo after contact with infectious brain homogenates. To date, among the neural cell lines, the mouse neuroblastoma-derived cell line N2a has been one of the most widely used model and has yet provided interesting insights into cell biology of prion propagation. Remarkably, persistently-infected N2a sublines have been set up and replicate prions without exhibiting any pathological changes. One further interesting feature of N2a is the possibility to establish by subcloning, sublines with a range of susceptibility to prions. Indeed, susceptible sublines propagate prions and accumulate the pathogenic isoform of the prion protein, PrPSc, at the opposite of resistant sublines. The aim of our study was to apply large-scale expression analysis using microarrays combined with quantitative real-time PCR to examine the gene expression profile in a persistently-infected N2a cell line, N2a58, infected with the mouse-adapted prion strain 22L, to seek for prion-specific gene transcription. We also questioned if we could observe identical variations of expression of these genes in three other 22L-infected N2a sublines. Finally, we examined the transcriptional state of a N2a subline considered as resistant when exposed to prions. Common pathways of gene transcription would disclose information on the molecular basis of the cell infection and help to identify potential therapeutic targets. Keywords: other

Project description:Manifestation of aggregate pathology in Huntington’s disease is thought to be facilitated by a preferential vulnerability of affected brain cells to age-dependent proteostatic decline. To understand how specific cellular backgrounds may facilitate pathologic aggregation, we utilized the yeast model in which polyQ-expanded Huntingtin forms aggregates only when the endogenous prion-forming protein Rnq1 is in its amyloid-like prion [PIN+] conformation. We employed optogenetic clustering of polyQ protein as an orthogonal method to induce polyQ aggregation in prion-free [pin-] cells. Optogenetic aggregation circumvented the prion requirement for the formation of detergent-resistant polyQ inclusions, but bypassed the formation of toxic polyQ oligomers, which accumulated specifically in [PIN+] cells. Reconstitution of aggregation in vitro suggested that these polyQ oligomers formed through direct templating on Rnq1 prions. These findings shed light on the mechanism of prion-mediated formation of oligomers, which may play a role in triggering polyQ pathology in the patient brain.

Project description:Prion infection in animals results in neurodegeneration and eventually death. To examine the cellular impact of Prion disease, we profiled non-proliferative fully differentiated C2C12 cells, which can replicate prions to high levels. Results suggest that accumulation of high levels of PrPSc in C2C12 myotubes does not cause any overt cellular dysfunction or molecular pathology. C2C12 cells were differentiated into confluent myotubes. Cells were infected or not with 100ul of 10% brain homogenate obtained from a C57BL/6 mouse clinically affected with RML prions. 16 days after infection, cells were collected by scraping and RML was purified.

Project description:Theory and experiment suggest that organisms would benefit from pre-adaptation to future stressors based on reproducible environmental fluctuations experienced by their ancestors. Yet mechanisms driving pre-adaptation remain enigmatic. We report that the [SMAUG+] prion allows yeast to anticipate nutrient repletion after periods of starvation, providing a strong selective advantage. By transforming the landscape of post-transcriptional gene expression, [SMAUG+] regulates the decision between two broad growth and survival strategies: mitotic proliferation or meiotic differentiation into a stress-resistant state. [SMAUG+] is common in laboratory yeast strains, where standard propagation practice produces regular cycles of nutrient scarcity followed by repletion. Distinct [SMAUG+] variants are also widespread in wild yeast isolates from multiple niches, establishing that prion polymorphs can be utilized in natural populations. Our data provide a striking example of how protein-based epigenetic switches, hidden in plain sight, can establish a transgenerational memory that integrates adaptive prediction into developmental decisions.