Glycosylinositol phospholipid anchors of the scrapie and cellular prion proteins contain sialic acid.

The only identified component of the scrapie prion is PrPSc, a glycosylinositol phospholipid (GPI)-linked protein that is derived from the cellular isoform (PrPC) by an as yet unknown posttranslational event. Analysis of the PrPSc GPI has revealed six different glycoforms, three of which are unprecedented. Two of the glycoforms contain N-acetylneuraminic acid, which has not been previously reported as a component of any GPI. The largest form of the GPI is proposed to have a glycan core consisting of Man alpha-Man alpha-Man-(NeuAc-Gal-GalNAc-)Man-GlcN-Ino. Identical PrPSc GPI structures were found for two distinct isolates or "strains" of prions which specify different incubation times, neuropathology, and PrPSc distribution in brains of Syrian hamsters. Limited analysis of the PrPC GPI reveals that it also has sialylated glycoforms, arguing that the presence of this monosaccharide does not distinguish PrPC from PrPSc.     

Prions and prion proteins

Neurodegenerative diseases of animals and humans including scrapie, bovine spongiform encephalopathy, and Creutzfeldt-Jakob disease are caused by unusual infectious pathogens called prions. There is no evidence for a nucleic acid in the prion, but diverse experimental results indicate that a host-derived protein called PrPSc is a component of the infectious particle. Experiments with scrapie-infected cultured cells show that PrPSc is derived from a normal cellular protein called PrPC through an unknown posttranslational process. We have analyzed the amino acid sequence and posttranslational modifications of PrPSc and its proteolytically truncated core PrP 27-30 to identify potential candidate modifications that could distinguish PrPSc from PrPC. The amino acid sequence of PrP 27-30 corresponds to that predicted from the gene and cDNA. Mass spectrometry of peptides derived from PrPSc has revealed numerous modifications including two N-linked carbohydrate moieties, removal of an amino-terminal signal sequence, and alternative COOH termini. Most molecules contain a glycosylinositol phospholipid (GPI) attached at Ser-231 that results in removal of 23 amino acids from the COOH terminus, whereas 15% of the protein molecules are truncated to end at Gly-228. The structure of the GPI from PrPSc has been analyzed and found to be novel, including the presence of sialic acid. Other experiments suggest that the N-linked oligosaccharides are not necessary for PrPSc formation. Although detailed comparison of PrPSc with PrPC is required, there is no obvious way in which any of the modifications might confer upon PrPSc its unusual physical properties and allow it to act as a component of the prion. If no chemical difference is found between PrPC and PrPSc, then the two isoforms of the prion protein may differ only in their conformations or by the presence of bound cellular components.     

Identification of low-density Triton X-100-insoluble plasma membrane microdomains in higher plants.

Low density Triton X-100-insoluble plasma membrane microdomains can be isolated from different mammalian cell types and are proposed to be involved in membrane trafficking, cell morphogenesis and signal transduction. Heterotrimeric G-proteins and their receptors are often associated with such domains, suggesting that these structures are involved in G-protein-coupled signaling. Here we report that detergent-insoluble plasma membrane microdomains also exist in higher plants and contain about 15% of membrane-bound heterotrimeric G-protein beta-subunit (Gbeta). Plasma membrane microdomains were isolated from tobacco leaves. They have low buoyant density relative to the surrounding plasma membrane, and are insoluble in Triton X-100 at 4 degrees C. Detergent-insoluble vesicles were examined by freeze-fracture electron microscopy. They have sizes in the range 100-400 nm, and often contain aggregated protein complexes. The majority of plasma membrane proteins cannot be detected in the Triton X-100-insoluble fraction, while few polypeptides are highly enriched. We identified six proteins with molecular masses of 22, 28, 35, 60, 67 and 94 kDa in detergent-insoluble fractions that are glycosylphosphatidylinositol (GPI)-anchored.     

Cationic lipopolyamines induce degradation of PrPSc in scrapie-infected mouse neuroblastoma cells

In prion diseases the endogenous prion protein (PrPC) is converted into an abnormally folded isoform, denoted PrPSc, which represents the major component of infectious scrapie prions. The mechanism of the conversion is largely unknown, but the conversion is thought to occur after PrPC has reached the plasma membrane. Here we show that exogenous administration of the cationic lipopolyamine DOSPA interfered with the accumulation of PrPSc in scrapie-infected neuroblastoma cells. Structural analysis of the compounds tested revealed that inhibition of PrPSc was specific for lipids with a headgroup composed of the polyamine spermine and a quarternary ammonium ion between the headgroup and the lipophilic tail. The cationic lipopolyamine DOSPA induced the cellular degradation of preexisting PrPSc aggregates within 12 hours and interfered with the de novo synthesis of PrPSc. Biosynthesis of PrPC, or the assembly of sphingolipid-cholesterol microdomains (rafts) on the plasma membrane, were not affected by this inhibitor. After removal of DOSPA and replating into normal medium propagation of PrPSc commenced, although initially at a reduced rate. Incubation of ScN2a cells in free spermidine had no inhibitory effect on the accumulation of PrPSc. Our results indicate that membrane targeting of a small polyamine molecule creates a potent inhibitor of PrPSc propagation and offers the possibility to degrade preexisting PrPSc aggregates in living cells.     

Modified cell ELISA to determine the solubilization of cell surface proteins: Applications in GPI-anchored protein purification

A major step in purifying membrane bound proteins involves the solubilization of the protein of interest from the cell membranes. Glycosylphosphatidyl inositol (GPI)-anchored proteins pose a singular problem in this solubilization step since they are found in detergent-resistant membrane complexes and accordingly are insoluble in cold Triton X-100. In this study we have developed a modified cell ELISA that determines the solubility of these cell surface proteins under various solubilization conditions. Using this non-radioactive method we show that the combination of saponin/Triton X-100 at 4 degrees C solubilized GPI-anchored proteins more efficiently than Triton X-100 at 4 degrees C. The combination of saponin/Triton X-100 at 4 degrees C avoids the potential of activating proteases that occurs when using Triton X-100 at 37 degrees C. Furthermore, our method also shows the saponin/Triton X-100 solubilized GPI-anchored proteins equivalent to the more expensive octyl beta-glucoside. This is a particularly important consideration in large-scale protein purification. This method obviates the need to use radioactivity, gel electrophoresis and immunoblotting procedures. The solubilization conditions determined by this modified ELISA are readily translated to the practical application of large-scale protein purification as demonstrated in the purification of two different recombinant GPI-anchored proteins, GPI-hB7-1 (CD80) and GPI-mICAM-1 (CD54).     

Cell biological studies of the prion protein

Studying PrPC and PrPSc in cell culture systems is advantageous because such systems contain all the organelles, membranes, and molecular cofactors that are likely to play an important role in the biology of the proteins. Using cultured cells expressing PrPC, we have discovered that this isoform constitutively cycles between the cell surface and an endocytic compartment, a process that is mediated by clathrin-coated pits and a putative PrPC receptor. We have also constructed stably transfected lines of CHO cells that express PrP molecules carrying mutations that are associated with familial prion diseases. The mutant PrP molecules in these cells are spontaneously converted to the PrPSc state, a phenomenon which has allowed us to analyze several key features of prion formation.     

Caveola-dependent endocytic entry of amphotropic murine leukemia virus

Early results suggested that the amphotropic murine leukemia virus (A-MLV) does not enter cells via endocytosis through clathrin-coated pits and this gammaretrovirus has therefore been anticipated to fuse directly with the plasma membrane. However, here we present data implicating a caveola-mediated endocytic entry route for A-MLV via its receptor Pit2. Caveolae belong to the cholesterol-rich microdomains characterized by resistance to nonionic detergents such as Triton X-100. Extraction of murine fibroblastic NIH 3T3 cells in cold Triton X-100 showed the presence of the A-MLV receptor Pit2 in detergent-insoluble microdomains. Using coimmunoprecipitation of cell extracts, we were able to demonstrate direct association of Pit2 with caveolin-1, the structural protein of caveolae. Other investigations revealed that A-MLV infection in contrast to vesicular stomatitis virus infection is a slow process (t(1/2) approximately 5 h), which is dependent on plasma membrane cholesterol but independent of NH4Cl treatment of cells; NH4Cl impairs entry via clathrin-coated pits. Furthermore, expression of dominant-negative caveolin-1 decreased the susceptibility to infection via Pit2 by approximately 70%. These results show that A-MLV can enter cells via a caveola-dependent entry route. Moreover, increase in A-MLV infection by treatment with okadaic acid as well as entry of fusion-defective fluorescent A-MLV virions in NIH 3T3 cells further confirmed our findings and show that A-MLV can enter mouse fibroblasts via an endocytic entry route involving caveolae. Finally, we also found colocalization of fusion-defective fluorescent A-MLV virions with caveolin-1 in NIH 3T3 cells. This is the first time substantial evidence has been presented implicating the existence of a caveola-dependent endocytic entry pathway for a retrovirus.     

The acid phosphatase positive organelles of the Giardia lamblia trophozoite contain a membrane bound cathepsin C activity

We found a dipeptidyl aminopeptidase activity in the parasitic protozoan Giardia lamblia with properties similar to the lysosomal cathepsin C of rat-liver lysosomes. Subcellular fractionation of this parasite indicated that the cathepsin C activity is located in organelles not distinguishable from the ones containing acid phosphatase, a known marker enzyme of Giardia lysosome-like peripheral vesicles. Contrary to the rat lysosomal enzyme, Giardia cathepsin C behaved like a membrane protein. Moreover, the enzyme was not solubilized by Triton X-100 or Triton X-100/SDS at 0 degrees C but could be substantially solubilized by octylglucoside, Triton X-100 at 37 degrees C or by a pretreatment with the cholesterol complexing agent beta-cyclodextrin before the Triton/SDS treatment carried out at 0 degrees C. These observations suggest that binding/anchorage of this enzyme to membranes occurs in cholesterol-rich microdomains.     

The role of the prion protein membrane anchor in prion infection

In transmissible spongiform encephalopathies (TSE or prion diseases) such as sheep scrapie, bovine spongiform encephalopathy and human Creutzfeldt-Jakob disease, normally soluble and protease-sensitive prion protein (PrP-sen or PrPC) is converted to an abnormal, insoluble and protease-resistant form termed PrP-res or PrPSc. PrP-res/PrPSc is believed to be the main component of the prion, the infectious agent of the TSE/prion diseases. Its precursor, PrP-sen, is anchored to the cell surface at the C-terminus by a co-translationally added glycophosphatidyl-inositol (GPI) membrane anchor which can be cleaved by the enzyme phosphatidyl-inositol specific phospholipase (PIPLC). The GPI anchor is also present in PrP-res, but is inaccessible to PIPLC digestion suggesting that conformational changes in PrP associated with PrP-res formation have blocked the PIPLC cleavage site. Although the GPI anchor is present in both PrP-sen and PrP-res, its precise role in TSE diseases remains unclear primarily because there are data to suggest that it both is and is not necessary for PrP-res formation and prion infection.     

Detection of cholesterol-rich microdomains in the inner leaflet of the plasma membrane

The C-terminal domain (D4) of perfringolysin O binds selectively to cholesterol in cholesterol-rich microdomains. To address the issue of whether cholesterol-rich microdomains exist in the inner leaflet of the plasma membrane, we expressed D4 as a fusion protein with EGFP in MEF cells. More than half of the EGFP-D4 expressed in stable cell clones was bound to membranes in raft fractions. Depletion of membrane cholesterol with beta-cyclodextrin reduced the amount of EGFP-D4 localized in raft fractions, confirming EGFP-D4 binding to cholesterol-rich microdomains. Subfractionation of the raft fractions showed most of the EGFP-D4 bound to the plasma membrane rather than to intracellular membranes. Taken together, these results strongly suggest the existence of cholesterol-rich microdomains in the inner leaflet of the plasma membrane.     

Immunolocalisation of PrPSc in scrapie-infected N2a mouse neuroblastoma cells by light and electron microscopy

The causative agent of transmissible spongiform encephalopathies (TSE) is PrPSc, an infectious, misfolded isoform of the cellular prion protein (PrPC). The localisation and trafficking of PrPSc and sites of conversion from PrPC to PrPSc are under debate, particularly since most published work did not discriminate between PrPC and PrPSc. Here we describe the localisation of PrPC and PrPSc in a scrapie-infected neuroblastoma cell line, ScN2a, by light and electron microscopic immunolocalisation. After eliminating PrPC with proteinase K, PrPSc was detected at the plasma membrane, endocytosed via clathrin-coated pits and delivered to early endosomes. Finally, PrPSc was detected in late endosomes/lysosomes. As we detected PrPSc at the cell surface, in early endosomes and in late endosomes/lysosomes, i.e. locations where PrPC is also present, our data imply that the conversion process could take place at the plasma membrane and/or along the endocytic pathway. Finally, we observed the release of PrPC/PrPSc via exocytotic pathways, i.e. via exosomes and as an opaque electron-dense mass which may represent a mechanism of intercellular spreading of infectious prions.     

KDEL-tagged anti-prion intrabodies impair PrP lysosomal degradation and inhibit scrapie infectivity

Transmissible spongiform encephalopathy or prion diseases are fatal neurodegenerative disorders characterized by the conversion of the cellular prion protein (PrPC) into the infectious scrapie isoform (PrPSc). We have recently demonstrated that anti-prion intrabodies targeted to the lumen of the endoplasmic reticulum provide a simple and effective means to inhibit the transport of PrPC to the cell surface. Here, we report that they completely block the traffic of mature full-length PrPC molecules, impair prion lysosomal degradation, and interfere with the early phase of scrapie formation. Since anti-prion intrabodies efficiently block PrPSc accumulation in vitro, we investigated whether they could also antagonize scrapie infectivity in vivo. We found that mice intracerebrally injected with KDEL-8H4-NGF-differentiated PC12 cells infected with scrapie neither develop scrapie clinical signs nor brain damage. Furthermore, no protease-resistant PrPSc is detectable in brains of inoculated animals. These results indicate that anti-prion intrabody strategy may be effective against prion infection.     

Identification of cellular proteins binding to the scrapie prion protein

The scrapie prion protein (PrPSc) is an abnormal isoform of the cellular protein PrPc. PrPSc is found only in animals with scrapie or other prion diseases. The invariable association of PrPSc with infectivity suggests that PrPSc is a component of the infectious particle. In this study, we report the identification of two proteins from hamster brain of 45 and 110 kDa (denoted PrP ligands Pli 45 and Pli 110) which were able to bind to PrP 27-30, the protease-resistant core of PrPSc on ligand blots. Pli 45 and Pli 110 also bound PrPC. Both Pli's had isoelectric points of approximately 5. The dissociation rate constant of the Pli 45/PrP 27-30 complex was 3 x 10(-6) s-1. Amino acid and protein sequence analyses were performed on purified Pli 45. Both the composition and the sequence were almost identical with those predicted for mouse glial fibrillary acidic protein (GFAP). Furthermore, antibodies to Pli 45 reacted with recombinant GFAP. The identification of proteins which interact with the PrP isoforms in normal and diseased brain may provide new insights into the function of PrPC and into the molecular mechanisms underlying prion diseases.     

Scrapie and cellular prion proteins differ in their kinetics of synthesis and topology in cultured cells

Both the cellular and scrapie isoforms of the prion protein (PrP) designated PrPc and PrPSc are encoded by a single-copy chromosomal gene and appear to be translated from the same 2.1-kb mRNA. PrPC can be distinguished from PrPSc by limited proteolysis under conditions where PrPC is hydrolyzed and PrPSc is resistant. We report here that PrPC can be released from the surface of both normal-control and scrapie-infected murine neuroblastoma (N2a) cells by phosphatidylinositol-specific phospholipase C (PIPLC) digestion and it can be selectively labeled with sulfo-NHS-biotin, a membrane impermeant reagent. In contrast, PrPSc was neither released by PIPLC nor labeled with sulfo-NHS-biotin. Pulse-chase experiments showed that [35S]methionine was incorporated almost immediately into PrPC while incorporation into PrPSc molecules was observed only during the chase period. While PrPC is synthesized and degraded relatively rapidly (t1/2 approximately 5 h), PrPSc is synthesized slowly (t1/2 approximately 15 h) and appears to accumulate. These results are consistent with several observations previously made on rodent brains where PrP mRNA and PrPC levels did not change throughout the course of scrapie infection, yet PrPSc accumulated to levels exceeding that of PrPC. Our kinetic studies demonstrate that PrPSc is derived from a protease-sensitive precursor and that the acquisition of proteinase K resistance results from a posttranslational event. Whether or not prolonged incubation periods, which are a cardinal feature of prion diseases, reflect the slow synthesis of PrPSc remains to be established.     

Retrovirus infection strongly enhances scrapie infectivity release in cell culture

Prion diseases are neurodegenerative disorders associated in most cases with the accumulation in the central nervous system of PrPSc (conformationally altered isoform of cellular prion protein (PrPC); Sc for scrapie), a partially protease-resistant isoform of the PrPC. PrPSc is thought to be the causative agent of transmissible spongiform encephalopathies. The mechanisms involved in the intercellular transfer of PrPSc are still enigmatic. Recently, small cellular vesicles of endosomal origin called exosomes have been proposed to contribute to the spread of prions in cell culture models. Retroviruses such as murine leukemia virus (MuLV) or human immunodeficiency virus type 1 (HIV-1) have been shown to assemble and bud into detergent-resistant microdomains and into intracellular compartments such as late endosomes/multivesicular bodies. Here we report that moloney murine leukemia virus (MoMuLV) infection strongly enhances the release of scrapie infectivity in the supernatant of coinfected cells. Under these conditions, we found that PrPC, PrPSc and scrapie infectivity are recruited by both MuLV virions and exosomes. We propose that retroviruses can be important cofactors involved in the spread of the pathological prion agent.     

Role of the FYVE finger and the RUN domain for the subcellular localization of Rabip4

Rabip4 is a Rab4 effector, which possesses a RUN domain, two coiled-coil domains, and a FYVE finger. It is associated with the early endosomes and leads, in concert with Rab4, to the enlargement of endosomes, resulting in the fusion of sorting and recycling endosomes. Our goal was to characterize the role of these various domains in Rabip4 subcellular localization and their function in Chinese hamster ovary cells. Although the FYVE finger domain specifically bound phosphatidylinositol 3-phosphate and was necessary for the function of Rabip4, it was not sufficient for the protein association with membranes. Indeed a protein containing the FYVE finger and the Rab4-binding site was cytosolic, whereas the total protein was mostly associated to the membrane fraction, whether or not cells were pretreated with wortmannin. By contrast, a construct corresponding to the N-terminal end, Rabip4-(1-212), and containing the RUN domain was membrane-associated. The complete protein partitioned between the Triton X-100-insoluble and -soluble fractions and a wortmannin treatment increased the amount of the protein in the Triton X-100 fraction. Rabip4-(1-212) was totally Triton X-100-insoluble, and confocal microscopic examination showed that it labeled not only the endosomes, positive for Rabip4, but also a filamentous network with a honeycomb appearance. The Triton X-100-insoluble fraction that contains Rabip4 did not correspond to the caveolin or glycosylphosphatidylinositol-enriched lipid rafts. Rabip4 did not appear directly linked to actin but seemed associated to the actin network. We propose that the subcellular localization of the protein is primarily driven by the RUN domain to endosomal microdomains characterized by Triton X-100 insolubility and that the FYVE domain and the Rab4-binding domain then allow for the recruitment of the protein to lipophilic microdomains enriched in phosphatidylinositol 3-phosphate.     

Evidence for synthesis of scrapie prion proteins in the endocytic pathway.

Infectious scrapie prions are composed largely, if not entirely, of an abnormal isoform of the prion protein (PrP) which is designated PrPSc. A chromosomal gene encodes both the cellular prion protein (PrPC) as well as PrPSc. Pulse-chase experiments with scrapie-infected cultured cells indicate that PrPSc is formed by a post-translational process. PrP is translated in the endoplasmic reticulum, modified as it passes through the Golgi, and is transported to the cell surface. Release of nascent PrP from the cell surface by phosphatidylinositol-specific phospholipase C or hydrolysis with dispase prevented PrPSc synthesis. At 18 degrees C, the synthesis of PrPSc was inhibited under conditions that other investigators report a blockage of endosomal fusion with lysosomes. Our results suggest that PrPSc synthesis occurs after PrP transits from the cell surface. Whether all of the PrP molecules have an equal likelihood to be converted into PrPSc or only a distinct subset is eligible for conversion remains to be established. Identifying the subcellular compartment(s) of PrPSc synthesis should be of considerable importance in defining the molecular changes that distinguish PrPSc from PrPC.     

GPI-anchored GFP signals Ca2+ but is homogeneously distributed on the cell surface

Glycosyl-phosphatidylinositol (GPI)-anchored proteins are unique in that they penetrate only the outer leaflet of the plasma membrane but are still able to mediate intracellular signalling events following antibody-induced ligation. Detergent solubilisation studies suggest that microdomains exist at the cell surface within which are sequestered GPI-linked proteins. Here we report the construction and expression of a fluorescent GPI anchor on the surface of CHO, EL4, and U937 cells by fusing green fluorescent protein (GFP) to the GPI-attachment site of CD59. The resultant GFP-GPI has properties comparable to that of endogenously expressed GPI-anchored molecules as shown by Triton X-114 partitioning. However, sucrose gradient floatation showed that GFP-GPI was only partially resistant to detergent solubilisation. Furthermore confocal scanning laser microscopy revealed a homogeneous distribution of GFP-GPI at the cell surface, which only became clustered following cross-linking of the GPI anchor via an anti-GFP antibody. Surprisingly, GFP-GPI signalled Ca2+ change upon cross-linking demonstrating its signalling competence. Our results suggest that the GPI-anchor itself does not confer a clustered distribution to molecules but that clustering occurs following ligation with antibody, which allows the protein to become Ca2+ signalling competent.     

Mutant prion protein-mediated aggregation of normal prion protein in the endoplasmic reticulum: implications for prion propagation and neurotoxicity

Familial prion disorders are believed to result from spontaneous conversion of mutant prion protein (PrPM) to the pathogenic isoform (PrPSc). While most familial cases are heterozygous and thus express the normal (PrPC) and mutant alleles of PrP, the role of PrPC in the pathogenic process is unclear. Plaques from affected cases reveal a heterogeneous picture; in some cases only PrPM is detected, whereas in others both PrPC and PrPM are transformed to PrPSc. To understand if the coaggregation of PrPC is governed by PrP mutations or is a consequence of the cellular compartment of PrPM aggregation, we coexpressed PrPM and PrPC in neuroblastoma cells, the latter tagged with green fluorescent protein (PrPC-GFP) for differentiation. Two PrPM forms (PrP231T, PrP217R/231T) that aggregate spontaneously in the endoplasmic reticulum (ER) were generated for this analysis. We report that PrPC-GFP aggregates when coexpressed with PrP231T or PrP217R/231T, regardless of sequence homology between the interacting forms. Furthermore, intracellular aggregates of PrP231T induce the accumulation of a C-terminal fragment of PrP, most likely derived from a potentially neurotoxic transmembrane form of PrP (CtmPrP) in the ER. These findings have implications for prion pathogenesis in familial prion disorders, especially in cases where transport of PrPM from the ER is blocked by the cellular quality control.     

Hsp70 binds to PrPC in the process of PrPC release via exosomes from THP-1 monocytes

PrPC (cellular prion protein) is a GPI (glycophosphatidylinositol)-anchored protein present on the surface of a number of peripheral blood cells. PrPC must be present for the generation and propagation of pathogenic conformer [PrPSc (scrapie prion protein)], which is a conformational conversion form of PrPC and has a central role in transmissible spongiform encephalopathies. It is important to determine the transportation mechanism of normal PrPC between cells. Exosomes are membrane vesicles released into the extracellular space upon fusion of multivesicular endosomes with the plasma membrane. We have identified that THP-1 monocytes can secrete exosomes to culture medium, and the secreted exosomes can bear PrPC. We also found that Hsp70 interacts with PrPC not only in intracellular environment, but in the secreted exosomes. However, the specific markers of exosomes, Tsg101 and flotillin-1, were found with no interaction with PrPC. Our results demonstrated that PrPC can be released from THP-1 monocytes via secreted exosomes, and in this process, Hsp70 binds to PrPC, which suggests that Hsp70 may play a potential functional role in the release of PrPC.