Project description:A key event in the pathogenic process of prion diseases is the conversion of the cellular prion protein (PrPC) to an abnormal and protease-resistant isoform (PrPSc). Mice lacking PrP are resistant to prion infection, and down-regulation of PrPC during prion infection prevents neuronal loss and the progression to clinical disease. These results are suggestive of the potential beneficial effect of silencing PrPC during prion diseases. However, the silencing of a protein that is widely expressed throughout the CNS could be detrimental to brain homeostasis. The physiological role of PrPC remains still unclear, but several putative functions have been proposed. Among these, several lines of evidence support PrPC function in neuronal development and maintenance. To assess the influence of PrPC on gene expression profile during development in the mouse brain, we undertook a microarray analysis by using RNA isolated from the hippocampus, at two different developmental stages: newborn (4-day-old) and adult (3-month-old) mice, both from Prnp+/+ and Prnp0/0 animals. The comparison of the different datasets allowed us to identify “commonly” co-regulated genes and “uniquely” de-regulated genes during postnatal development in these animal models. The lack of PrPC during neuronal development affected several biological pathways, among which the most representative were cell signaling, cell-cell communication and transduction process. In addition, the absence of PrPC influenced genes involved in calcium homeostasis, nervous system development, synaptic transmission and cell adhesion. There was only a moderate alteration of the gene expression profile during neuronal development in the animal models we studied. PrPC deficiency does not lead to a dramatic alteration of gene expression profile, and produces moderate altered gene expression levels from young to adult animals. Thus, our results may provide additional support to silencing endogenous PrPC levels as a therapeutic approach to prion diseases. To analyze the influence of PrPC expression on CNS gene expression profile during development, we investigated WT PrPC (Prnp+/+) and Prnp0/0 mice at two different developmental stages: in neonatal animals (postnatal day 4, P4) and in adult animals (3 months old). For each developmental stage, hippocampi of 3 (pups) or 4 (adult) animals were dissected immediately after animal sacrifice and promptly processed for RNA extraction and purification, for a total of 14 samples.

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 consist of aggregates of abnormal conformers of cellular prion protein (PrPC). They propagate by recruiting host-encoded PrPC although the critical interacting proteins and the reasons for the differences in susceptibility of distinct cell lines and populations are unknown. We derived a lineage of cell lines with markedly differing susceptibilities, unexplained by PrPC expression differences, to identify such factors. We examined the transcriptomes of prion-resistant revertants, isolated from highly susceptible cells, and identified a gene expression signature associated with susceptibility. Several of these genes encode proteins with a role in extracellular matrix (ECM) remodelling, a compartment in which disease-related PrP deposits. Loss-of-function of nine of these genes significantly increased susceptibility. Remarkably, inhibition of fibronectin 1 binding to integrin α8 by RGD peptide inhibited metalloproteinases (MMP)-2/9 whilst increasing prion propagation rates. This indicates that prion replication may be controlled by MMPs at the ECM in an integrin-dependent manner.

Project description:Prions cause transmissible neurodegenerative diseases and replicate by conformational conversion of normal, benign forms of prion protein (PrPC) to disease-causing PrPSc isoforms. A systems approach to disease postulates that disease arises from the pathological perturbation (genetic and/or environmental) of one or more biological networks in the relevant organ. In this regard, we tracked global (all mRNA transcripts) gene expression in the brains of eight distinct mouse strain-prion strain combinations at 8 - 10 time points throughout the progression of the disease to capture the effects of prion strain, host genetics, and PrP concentration on disease incubation time. Data are also available from http://prion.systemsbiology.net

Project description:The endogenous cellular prion protein (PrPC) can misfold into the scrapie isoform (PrPSc) and cause fatal infectious diseases. Despite significant research on the prion protein, both its normal function and whether alterations to that function play a critical role in prion diseases remain unknown. The protein consists of a predominantly alpha-helical C-terminal domain and an unstructured N-terminal domain that can coordinate Cu2+. Previous studies using NMR and EPR have revealed a tertiary association between the N-terminal domain and the C-terminal domain that we have hypothesized to be critical to the protein’s normal function. Here we investigated and quantified the inter-domain interactions within three different prion variants (wild type recombinant mouse PrPC, mutant delta central region (ΔCR), and disease mutant (E199K) after chemical cross-linking with a newly designed MS-cleavable reagent 1-(4-((2,5-Dioxopyrrolidin-1-yl)oxy)-4-oxobutyl)-4-(2-(3-methyl-3H-diazirin-3-yl)ethyl)-1,4-diazabicyclo[2.2.2] octane-1,4-diium (APDC4), followed by nHPLC(RP) and tandem MS analysis.

Project description:Cellular prion protein (PrPC) is a high-affinity cell-surface receptor for Amyloid-β oligomers(Aßo). In certain overexpression models of Alzheimer’s Disease (AD), pharmacology and genetics demonstrate its essential role for synaptic plasticity impairment, memory deficits and synapse loss. However, PrPC ’s role in AD-related phenotypes with endogenous expression levels, its role in tau accumulation and its effect on imaging biomarkers are unknown. The necessity of PrPC for transcriptomic alterations driven by Aß across cell types is unexplored.

Project description:The underlying pathogenic mechanisms of prion infection are not well characterized. To study the effect of prion infection on gene expression in neuronal cell cultures, a neuroblastoma (N2a) cell clone was infected with either the mouse adapted prion strain 22L or exposed to uninfected brain homogenate as a negative control. Large scale expression analysis was performed using a cDNA microarray chip comprising about 21,000 spotted ESTs. Over hundred genes were identified that are differentially expressed in 22L-infected cells when compared to uninfected cells. Several of the identified changes in gene expression have also been reported for other neurodegenerative diseases such as Alzheimer`s disease. Keywords: cDNA arrays, prion, N2a, neuroblastoma cell line, murine A neuroblastoma (N2a) cell clone was infected with either the mouse adapted prion strain 22L or exposed to uninfected brain homogenate as a negative control. Eight replicates including four dye swap experiments have been performed for the comparison of prion infected cells versus control cells.

Project description:MicroRNAs (miRNAs) are evolutionary conserved, non-coding, gene regulatory RNA molecules found in both plants and animals and amongst almost every cell and tissue type. They are about 22 nucleotides long and are involved in silencing of mRNA through sequence specific binding to the 3’ untranslated region (UTR) of the mRNA subsequently causing translational repression and/or will promote the degradation of protein-coding mRNA. Specifically, the miRNA family, mir-146 a/b, has been previously found to be involved in the regulation of the innate immune response by functioning as a negative regulator to help fine-tune the immune response. Microglial cells are the macrophage of the brain participating as major players of the innate immune response. During prion disease, no immune response is mounted against PrPSc possibly due to its similarity to host PrPc and thus, the host immune response would be suppressed and tightly regulated. Therefore, an increased expression of mir-146 by microglial cells during prion disease may function as one of these negative regulators. Our objective of this experiment is to use DNA microarrays to investigate the gene regulation of mir-146 previously found upregulated in our studies of mouse brain tissue specifically in microglial cells during prion disease with the aim of having a better understanding of prion pathobiology and a potential target for therapeutic intervention.

Project description:Prion diseases are rare, neurological disorders caused by the misfolding of the cellular prion protein (PrPC). The misfolded conformers aggregate into cytotoxic fibrils (PrPSc) that facilitate the conversion of additional prion proteins into their misfolded form. Intracellular PrPSc aggregates primarily accumulate within late endosomes and lysosomes, organelles that participate in the degradation and turnover of a large subset of the proteome. Thus, intracellular accumulation of PrPSc aggregates have the potential to globally influence protein degradation kinetics. We have analyzed the proteome-wide effect of prion infection on protein degradation rates in N2a neuroblastoma cells by dynamic stable isotopic labeling with amino acids in cell culture (dSILAC) and bottom-up proteomics to quantify the degradation rates of more than 4700 proteins in prion-infected and uninfected cells. As expected, the degradation rate of the prion protein is significantly decreased upon aggregation in infected cells. The data indicate that dilution due to cell division, rather than degradation, is the dominant factor in clearance of PrPSc in infected N2a cells. Conversely, the degradation kinetics of the remainder of the N2a proteome generally increases upon infection. This effect occurs concurrently with increases in the cellular activities of autophagy and lysosomal hydrolases. The resulting enhancement in proteome flux may play a role in the survival of N2a cells during prion infection.

Project description:The underlying pathogenic mechanisms of prion infection are not well characterized. To study the effect of prion infection on gene expression in neuronal cell cultures, a neuroblastoma (N2a) cell clone was infected with either the mouse adapted prion strain 22L or exposed to uninfected brain homogenate as a negative control. Large scale expression analysis was performed using a cDNA microarray chip comprising about 21,000 spotted ESTs. Over hundred genes were identified that are differentially expressed in 22L-infected cells when compared to uninfected cells. Several of the identified changes in gene expression have also been reported for other neurodegenerative diseases such as Alzheimer`s disease. Keywords: cDNA arrays, prion, N2a, neuroblastoma cell line, murine