The Cellular Prion Protein Increases the Uptake and Toxicity of TDP-43 Fibrils.

Cytoplasmic aggregation of the primarily nuclear TAR DNA-binding protein 43 (TDP-43) affects neurons in most amyotrophic lateral sclerosis (ALS) and approximately half of frontotemporal lobar degeneration (FTLD) cases. The cellular prion protein, PrPC, has been recognized as a common receptor and downstream effector of circulating neurotoxic species of several proteins involved in neurodegeneration. Here, capitalizing on our recently adapted TDP-43 real time quaking induced reaction, we set reproducible protocols to obtain standardized preparations of recombinant TDP-43 fibrils. We then exploited two different cellular systems (human SH-SY5Y and mouse N2a neuroblastoma cells) engineered to express low or high PrPC levels to investigate the link between PrPC expression on the cell surface and the internalization of TDP-43 fibrils. Fibril uptake was increased in cells overexpressing either human or mouse prion protein. Increased internalization was associated with detrimental consequences in all PrP-overexpressing cell lines but was milder in cells expressing the human form of the prion protein. As described for other amyloids, treatment with TDP-43 fibrils induced a reduction in the accumulation of the misfolded form of PrPC, PrPSc, in cells chronically infected with prions. Our results expand the list of misfolded proteins whose uptake and detrimental effects are mediated by PrPC, which encompass almost all pathological amyloids involved in neurodegeneration.

Strain Typing of Prion Diseases Using In Vivo Mouse Models.

Transmissible spongiform encephalopathies (TSE) or prion diseases exhibit strain variation, a phenomenon that has been studied extensively in mouse bioassays. Despite the introduction of many rapid in vitro systems, bioassays remain a key tool in defining prion strains and their ability to transmit disease in vivo. Prion strains can be characterized by a range of phenotypic characteristics such as incubation period, vacuolar pathology, and distribution of the abnormal form of PrP following experimental transmission of the agent into a panel of mice (transgenic or wild type). Interpretation of these characteristics requires considerable experience and an understanding of the procedures used to define them. This chapter reviews the techniques used in strain typing of prion diseases from inoculum preparation and pathological studies to data interpretation alongside an extensive troubleshooting guide.

Strain specificity and drug resistance in anti-prion therapy.

Prion diseases are a group of fatal neurodegenerative diseases caused by the misfolding of cellular prion protein (PrP(C)) into pathogenic conformers (PrP(Sc)). Although no effective therapies for prion diseases are currently available, a number of small molecule inhibitors have been identified that are capable of reducing or eliminating PrP(Sc) in prion infected cells. However, recent experiments have shown that upon sustained treatment, prions have the capacity to evolve into drug resistant conformations. These studies suggest that the mechanism of prion strain adaptation involves rare conformational conversions followed by competitive selection among the heterogeneous pool of PrP(Sc) conformers. The plasticity of prion conformers makes PrP(Sc) a particularly challenging drug target and suggests that combination drug therapies or targeting of PrP(C) may be required for effective therapy. In this review, we highlight recent literature that demonstrate the phenomenon of prion drug resistance and strain specificity, and discuss potential ramifications for therapeutic efforts against prion diseases.

Regional phenotypes of cellular prion proteins in human brains identified by differential detergent solubility.

A hallmark of prion diseases is the accumulation of disease-associated isoforms (PrP(Sc)) which results from the conversion of host-encoded cellular prion proteins (PrP(C)). Using molecular biochemistry, several disease variants of the human Creutzfeldt-Jakob disease have been identified showing several PrP(Sc) variants in individuals and selective accumulation in specific brain regions. As PrP(C) is differentially expressed and post-translationally modified, certain distinct protein compositions may have the ability to convert more efficiently than others. The PrP(C) glycoprotein moiety represents a single yet divers mixture, but little is known about its exact composition. In this study, we separated and characterized PrP(C) derived from six defined human brain regions in regard to their solubility in several detergent solutions and glycoprotein profile formation. We identified four different but regionally distinct protein compositions. PrP(C) found in the neocortex exhibited dominant diglycosylated bands in the high as well as in the low soluble fractions. The proteins in the nucleus lentiformis, thalamus and hippocampus were more soluble with deoxycholic acid as the N-octyl-ß-d-glucopyranoside and the diglycosylated bands displayed strong signals in the supernatants and weaker signals in the sediments. Two different protein profiles were established with PrP(C) derived from the medulla oblongata and the solubility of PrP(C) in the cerebellum clearly differed by the choice of detergent. Our findings indicate the existence of several distinct PrP(C) compositions localized in distinct brain regions. Protein variations may be induced by specific modifications to specific regional biological functions.

Correlation of polydispersed prion protein and characteristic pathology in the thalamus in variant Creutzfeldt-Jakob disease: implication of small oligomeric species.

The vacuolation, neuronal loss and gliosis that characterize human prion disease pathology are accompanied by the accumulation of an aggregated, insoluble and protease-resistant form (termed PrP(Sc)) of the host-encoded normal cellular prion protein (PrP(C)). In variant Creutzfeldt-Jakob disease the frontal cortex and cerebellum exhibit intense vacuolation and the accumulation of PrP(Sc) in the form of amyloid plaques and plaque-like structures. In contrast the posterior thalamus is characterized by intense gliosis and neuronal loss, but PrP(Sc) plaques are rare and vacuolation is patchy. We have used sucrose density gradient centrifugation coupled with conformation dependent immunoassay to examine the biochemical properties of the PrP(Sc) that accumulates in these different brain regions. The results show a greater degree of PrP(Sc) polydisperal in thalamus compared with frontal cortex or cerebellum, including a subpopulation PrP(Sc) molecules in the thalamus that have sedimentation properties resembling those of PrP(C). Much effort has focused on identifying aspects of PrP(Sc) biochemistry that distinguish between different forms of human prion disease and contribute to differential diagnosis. Here we show that PrP(Sc) sedimentation properties, which can depend on aggregation state, correlate with, and may underlie the distinct neurodegenerative processes occurring in different regions of the variant Creutzfeldt-Jakob disease brain.

Characterization of prion protein (PrP)-derived peptides that discriminate full-length PrPSc from PrPC.

On our initial discovery that prion protein (PrP)-derived peptides were capable of capturing the pathogenic prion protein (PrP(Sc)), we have been interested in how these peptides interact with PrP(Sc). After screening peptides from the entire human PrP sequence, we found two peptides (PrP(19-30) and PrP(100-111)) capable of binding full-length PrP(Sc) in plasma, a medium containing a complex mixture of other proteins including a vast excess of the normal prion protein (PrP(C)). The limit of detection for captured PrP(Sc) was calculated to be 8 amol from a approximately 10(5)-fold dilution of 10% (wt/vol) human variant Creutzfeldt-Jakob disease brain homogenate, with >3,800-fold binding specificity to PrP(Sc) over PrP(C). Through extensive analyses, we show that positively charged amino acids play an important, but not exclusive, role in the interaction between the peptides and PrP(Sc). Neither hydrophobic nor polar interactions appear to correlate with binding activity. The peptide-PrP(Sc) interaction was not sequence-specific, but amino acid composition affected binding. Binding occurs through a conformational domain that is only present in PrP(Sc), is species-independent, and is not affected by proteinase K digestion. These and other findings suggest a mechanism by which cationic domains of PrP(C) may play a role in the recruitment of PrP(C) to PrP(Sc).

Games played by rogue proteins in prion disorders and Alzheimer's disease.

The incidence of Alzheimer's disease (AD) and that of prion disorders (PrD) could not be more different. One-third of octogenarians succumb to AD, whereas Creutzfeldt-Jakob disease typically affects one individual in a million each year. However, these diseases have many common features impinging on the metabolism of neuronal membrane proteins: the amyloid precursor protein APP in the case of AD, and the cellular prion protein PrPC in PrD. APP begets the Abeta peptide, whereas PrPC begets the malignant prion protein PrPSc. Both Abeta and PrPSc are associated with disease, but we do not know what triggers their accumulation and neurotoxicity. A great deal has been learned, however, about protein folding, misfolding, and aggregation; an entirely new class of intramembrane proteases has been identified; and unsuspected roles for the immune system have been uncovered. There is reason to expect that prion research will profit from advances in the understanding of AD, and vice versa.