Albert Taraboulos

CHARACTERIZATION OF DETERGENT-INSOLUBLE COMPLEXES CONTAINING THE CELLULAR PRION PROTEIN AND ITS SCRAPIE ISOFORM

Cells infected with prions contain both prion protein isoforms cellular prion protein (PrPC) and scrapie prion protein (PrPSc). PrPSc is formed posttranslationally through the pathological refolding of PrPC. In scrapie-infected ScN2a cells, the metabolism of both PrP isoforms involves cholesterol-dependent pathways. We show here that both PrPC and PrPSc are attached to Triton X-100-insoluble, low-density complexes or “rafts.” These complexes are sensitive to saponin and thus probably contain cholesterol. This finding suggests that the transformation PrPC → PrPSc occurs within rafts. It also reveals the existence of rafts in late compartments of the endocytic pathway, where most PrPSc resides. When Triton X-100 lysates of cells were incubated at 37°C prior to density analysis, PrPC was still found in buoyant complexes, although it now failed to sediment at high speed. This property was shared by another glycophosphatidyl inositol protein, Thy-1, and also by the raft resident GM1. In one ScN2a clone and in the brain of a Syrian hamster with scrapie, Triton X-100 extraction at 37°C permitted resolution of PrPC and PrPSc into two distinct peaks of different densities. This suggests that there are two populations of PrP-containing rafts and may permit isolation of PrPC-specific rafts from those containing PrPSc. Our findings reinforce the contention that rafts are involved in various aspects of PrP metabolism and in the “life cycle” of prions.

Proteasomes and ubiquitin are involved in the turnover of the wild‐type prion protein

Prion diseases propagate by converting a normal glycoprotein of the host, PrPC, into a pathogenic ‘prion’ conformation. Several misfolding mutants of PrPC are degraded through the ER‐associated degradation (ERAD)–proteasome pathway. In their infectious form, prion diseases such as bovine spongiform encephalopathy involve PrPC of wild‐type sequence. In contrast to mutant PrP, wild‐type PrPC was hitherto thought to be stable in the ER and thus immune to ERAD. Using proteasome inhibitors, we now show that ∼10% of nascent PrPC molecules are diverted into the ERAD pathway. Cells incubated with N‐acetyl‐leucinal‐leucinal‐norleucinal (ALLN), lactacystin or MG132 accumulated both detergent‐soluble and insoluble PrP species. The insoluble fraction included an unglycosylated 26 kDa PrP species with a protease‐resistant core, and a Mr ‘ladder’ that contained ubiquitylated PrP. Our results show for the first time that wild‐type PrPC molecules are subjected to ERAD, in the course of which they are dislocated into the cytosol and ubiquitylated. The presence of wild‐type PrP molecules in the cytosol may have potential pathogenic implications.

Rapid detection of Creutzfeldt‐Jakob disease and scrapie prion proteins

Creutzfeldt-Jakob disease (CJD) and Gerstmann-Sträussler syndrome (GSS) of humans as well as scrapie of animals are caused by prions. The scrapie prion protein isoform (PrPSc) is the only macromolecule identified to date which is a component of the infectious prion particle. PrPSc is converted to PrP 27-30 by limited proteolysis while the cellular isoform, designated PrPc, is completely digested under the same conditions. ELISA studies demonstrated that native PrP 27-30 bound to plastic surfaces resisted proteolysis and exhibited little or no immunoreactivity but after denaturation with guanidinium thiocyanate (GdnSCN), immunoreactivity was greatly enhanced. PrPSc bound to nitrocellulose also exhibited enhanced immunoreactivity after denaturation. PrPSc was readily detected in brain extracts from scrapie-infected hamsters, mice, and sheep by dot-blot immunoassays using limited proteolysis followed by GdnSCN denaturation. The high sensitivity and specificity of the immunoassay allowed detection of regional differences in PrPSc in sheep brain. CJD prion protein isoform (PrPCJD) was also detected in the brains of all 10 patients tested with neuropathologically confirmed CJD and in 1 patient with GSS. Enhanced immunoreactivity of PrPSc or PrPCJD after denaturation cannot only be used for immunodiagnosis of prion diseases but may also form the basis of new assays in experimental studies directed at the chemical structure of the prion particle.

A deleterious mutation in DNAJC6 encoding the neuronal-specific clathrin-uncoating co-chaperone auxilin, is associated with juvenile parkinsonism.

Parkinson disease is caused by neuronal loss in the substantia nigra which manifests by abnormality of movement, muscle tone, and postural stability. Several genes have been implicated in the pathogenesis of Parkinson disease, but the underlying molecular basis is still unknown for ∼70% of the patients. Using homozygosity mapping and whole exome sequencing we identified a deleterious mutation in DNAJC6 in two patients with juvenile Parkinsonism. The mutation was associated with abnormal transcripts and marked reduced DNAJC6 mRNA level. DNAJC6 encodes the HSP40 Auxilin, a protein which is selectively expressed in neurons and confers specificity to the ATPase activity of its partner Hcs70 in clathrin uncoating. In Auxilin null mice it was previously shown that the abnormally increased retention of assembled clathrin on vesicles and in empty cages leads to impaired synaptic vesicle recycling and perturbed clathrin mediated endocytosis. Endocytosis function, studied by transferring uptake, was normal in fibroblasts from our patients, likely because of the presence of another J-domain containing partner which co-chaperones Hsc70-mediated uncoating activity in non-neuronal cells. The present report underscores the importance of the endocytic/lysosomal pathway in the pathogenesis of Parkinson disease and other forms of Parkinsonism.

Cellular Heparan Sulfate Participates in the Metabolism of Prions

During prion diseases, the host protein PrPC is refolded into an abnormal conformer “prion” PrPSc. Histological and pharmacological data have suggested that glycosaminoglycans may be involved in the development of prion diseases. Here we present the first direct evidence that cellular glycosaminoglycans play a role in the biogenesis of PrPSc in prion-infected ScN2a cells. When ScN2a cells were incubated with estradiol β-d-xyloside to inhibit the glycosylation of proteoglycans, PrPSc was vastly reduced. Treating ScN2a-M cells with heparinase III, but not with heparinase I or chondroitinase ABC, caused a profound reduction of PrPSc. In contrast, neither the amount of PrPC nor its subcellular distribution were affected as assayed by immunofluorescence microscopy and flotation procedures. In vitro treatment of ScN2a membranes with heparinase III at either neutral or acidic pH did not reduce the level of protease-resistant PrPSc. The inhibitor of sulfation, sodium chlorate, vastly reduces PrPSc in ScN2a cells (Gabizon, R., Meiner, Z., Halimi, M., and Ben-Sasson, S. A. (1993) J. Cell. Physiol. 157, 319–325). Both soluble heparan sulfate and chondroitin sulfate partially restored the level of PrPSc in chlorate-treated cells. We conclude that heparinase III-sensitive, presumably undersulfated, cellular heparan sulfate plays a significant role in the biogenesis of PrPSc in ScN2a cells.

Modulation of proteinase-K resistant prion protein by prion peptide immunization.

Prion diseases are caused by conformational alterations in the prion protein (PrP). The immune system has been assumed to be non‐responsive to the self‐prion protein, therefore, PrP autoimmunity has not been investigated. Here, we immunized various strains of mice with PrP peptides, some selected to fit the MHC class II‐peptide binding motif. We found that specific PrP peptides elicited strong immune responses in NOD, C57BL/6 and A/J mice. To test the functional effect of this immunization, we examined the expression of proteinase‐K‐resistant PrP by a scrapie‐infected tumor transplanted to immunized syngeneic A/J mice. PrP peptide vaccination did not affect the growth of the infected tumor transplant, but significantly reduced the level of protease‐resistant PrP. Our results demonstrate that self‐PrP peptides are immunogenic in mice and suggest that this immune response might affect PrP‐scrapie levels in certain conditions.

Scrapie prions alter receptor‐mediated calcium responses in cultured cells

The molecular basis of neurologic dysfunction in prion diseases is unknown. Spongiform degeneration of neurons is the most characteristic neuropathologic change which raises the possibility of abnormal ion channel function. Here we examined the regulation of Ca2+ fluxes in two cell lines chronically infected with scrapie prions, designated ScN2a (scrapie-infected mouse neuroblatoma) and ScHaB (scrapie-infected hamster brain) cells. In uninfected HaB cells, bradykinin caused increases in iritracellular Ca2+ concentration ([Ca2+]i) by release of Ca2+ from internal stores and influx of extracellular Ca2+ whereas, in N2a cells, bradykinin increased [Ca2+]i exclusively from internal stores. Prion infection of both cell lines markedly reduced or eliminated bradykinin-activated increases in [Ca2+]i, whether driven by internal or extracellular sources. Stressing the cells with high extracellular [Ca2+], 8 to 20 mM, led to cytopathologic changes in ScHaB but not in ScN2a cells. Cytopathology was not preceded by an increase in [Ca2+]i. These findings indicate that scrapie infection induces abnormalities in receptor-mediated Ca2+ responses and raise the possibility that nerve cell dysfunction and degeneration in prion diseases is related to ion channel aberrations.

Scrapie-infected mice and PrP knockout mice share abnormal localization and activity of neuronal nitric oxide synthase.

Abstract : PrPSc, the only identified component of the scrapie prion, is a conformational isoform of PrPc. The physiological role of PrPc, a glycolipid‐anchored glycoprotein, is still unknown. We have shown previously that neuronal nitric oxide synthase (nNOS) activity is impaired in the brains of mice sick with experimental scrapie as well as in scrapie‐infected neuroblastoma cells. In this work we investigated the cell localization of nNOS in brains of wild‐type and scrapie‐infected mice as well as in mice in which the PrP gene was ablated. We now report that whereas in wild‐type mice, nNOS, like PrPc, is associated with detergent‐insoluble cholesterol‐rich membranous microdomains (rafts), this is not the case in brains of scrapie‐infected or in those of adult PrP% mice. Also, adult PrP%, like scrapie‐infected mice, show reduced nNOS activity. We suggest that PrPc may play a role in the targeting of nNOS to its proper subcellular localization. The similarities of nNOS properties in PrP% as compared with scrapie‐infected mice suggest that at least this role of PrPc may be impaired in scrapie‐infected brains.

Protease-resistant and Detergent-insoluble Prion Protein Is Not Necessarily Associated with Prion Infectivity

PrPSc, an abnormal isoform of PrPC, is the only known component of the prion, an agent causing fatal neurodegenerative disorders such as bovine spongiform encephalopathy (BSE) and Creutzfeldt-Jakob disease (CJD). It has been postulated that prion diseases propagate by the conversion of detergent-soluble and protease-sensitive PrPC molecules into protease-resistant and insoluble PrPSc molecules by a mechanism in which PrPSc serves as a template. We show here that the chemical chaperone dimethyl sulfoxide (Me2SO) can partially inhibit the aggregation of either PrPSc or that of its protease-resistant core PrP27–30. Following Me2SO removal by methanol precipitation, solubilized PrP27–30 molecules aggregated into small and amorphous structures that did not resemble the rod configuration observed when scrapie brain membranes were extracted with Sarkosyl and digested with proteinase K. Interestingly, aggregates derived from Me2SO-solubilized PrP27–30 presented less than 1% of the prion infectivity obtained when the same amount of PrP27–30 in rods was inoculated into hamsters. These results suggest that the conversion of PrPC into protease-resistant and detergent-insoluble PrP molecules is not the only crucial step in prion replication. Whether an additional requirement is the aggregation of newly formed proteinase K-resistant PrP molecules into uniquely structured aggregates remains to be established.

Processing and Degradation of Exogenous Prion Protein by CD11c+ Myeloid Dendritic Cells In Vitro

ABSTRACT The immune system plays an important role in facilitating the spread of prion infections from the periphery to the central nervous system. CD11c+ myeloid dendritic cells (DC) could, due to their subepithelial location and their migratory capacity, be early targets for prion infection and contribute to the spread of infection. In order to analyze mechanisms by which these cells may affect prion propagation, we studied in vitro the effect of exposing such DC to scrapie-infected GT1-1 cells, which produce the scrapie prion protein PrPSc. In this system, the DC efficiently engulfed the infected GT1-1 cells. Unexpectedly, PrPSc, which is generally resistant to protease digestion, was processed and rapidly degraded. Based on this observation we speculate that CD11c+ DC may play a dual role in prion infections: on one hand they may facilitate neuroinvasion by transfer of the infectious agent as suggested from in vivo studies, but on the other hand they may protect against the infection by causing an efficient degradation of PrPSc. Thus, the migrating and highly proteolytic CD11c+ myeloid DC may affect the balance between propagation and clearance of PrPSc in the organism.