Branched polyamines cure prion-infected neuroblastoma cells

Branched polyamines, including polyamidoamine and polypropyleneimine (PPI) dendrimers, are able to purge PrP(Sc), the disease-causing isoform of the prion protein, from scrapie-infected neuroblastoma (ScN2a) cells in culture (S. Supattapone, H.-O. B. Nguyen, F. E. Cohen, S. B. Prusiner, and M. R. Scott, Proc. Natl. Acad. Sci. USA 96:14529-14534, 1999). We now demonstrate that exposure of ScN2a cells to 3 microg of PPI generation 4.0/ml for 4 weeks not only reduced PrP(Sc) to a level undetectable by Western blot but also eradicated prion infectivity as determined by a bioassay in mice. Exposure of purified RML prions to branched polyamines in vitro disaggregated the prion rods, reduced the beta-sheet content of PrP 27-30, and rendered PrP 27-30 susceptible to proteolysis. The susceptibility of PrP(Sc) to proteolytic digestion induced by branched polyamines in vitro was strain dependent. Notably, PrP(Sc) from bovine spongiform encephalopathy-infected brain was susceptible to PPI-mediated denaturation in vitro, whereas PrP(Sc) from natural sheep scrapie-infected brain was resistant. Fluorescein-labeled PPI accumulated specifically in lysosomes, suggesting that branched polyamines act within this acidic compartment to mediate PrP(Sc) clearance. Branched polyamines are the first class of compounds shown to cure prion infection in living cells and may prove useful as therapeutic, disinfecting, and strain-typing reagents for prion diseases.     

Chimeric prion protein expression in cultured cells and transgenic mice.

The efficient expression of exogenous prion protein (PrP) molecules in mouse neuroblastoma cells that are chronically infected with murine scrapie prions (ScN2a cells; Butler, D.A., et al., 1988, J. Virol. 62, 1558-1564) and in transgenic mice is described. This technology allows investigation of the PrP molecule for structural regions involved in determining species specificity, as well as ablation experiments designed to address the functionality of particular regions of the PrP molecule. Previous reports demonstrated that the PrP gene specifies the host range for susceptibility of transgenic animals to prions (Scott, M., et al., 1989, Cell 59, 847-857; Prusiner, S.B., et al., 1990, Cell 63, 673-686). Consistent with these results, we showed that Syrian hamster (SHa) PrP is ineligible for efficient conversion to PrPSc in ScN2a cells. By constructing a series of chimeric mouse (Mo)/SHaPrP genes, we developed an epitopically tagged functional variant of the MoPrP gene, which can efficiently form protease-resistant PrP molecules upon expression in ScN2a cells. The presence of a defined epitope for an SHa-specific monoclonal antibody allows the products of this chimeric gene to be discriminated from endogenous MoPrP and creates a useful reagent for exploring structure/function relationships via targeted mutagenesis. In addition, we developed a transgenic mouse expression vector by manipulation of an SHaPrP cosmid clone. This vector permits the efficient expression of foreign PrP genes in the brains of transgenic animals, enabling pathological consequences of in vitro mutagenesis to be studied.     

Intramolecular versus intermolecular disulfide bonds in prion proteins

Prion protein (PrP) is the major component of the partially protease-resistant aggregate that accumulates in mammals with transmissible spongiform encephalopathies. The two cysteines of the scrapie form, PrP(Sc), were found to be in their oxidized (i.e. disulfide) form (Turk, E., Teplow, D. B., Hood, L. E., and Prusiner, S. B. (1988) Eur. J. Biochem. 176, 21-30); however, uncertainty remains as to whether the disulfide bonds are intra- or intermolecular. It is demonstrated here that the monomers of PrP(Sc) are not linked by intermolecular disulfide bonds. Furthermore, evidence is provided that PrP(Sc) can induce the conversion of the oxidized, disulfide-intact form of the monomeric cellular prion protein to its protease-resistant form without the temporary breakage and subsequent re-formation of the disulfide bonds in cell-free reactions.     

A protease-resistant 61-residue prion peptide causes neurodegeneration in transgenic mice

An abridged prion protein (PrP) molecule of 106 amino acids, designated PrP106, is capable of forming infectious miniprions in transgenic mice (S. Supattapone, P. Bosque, T. Muramoto, H. Wille, C. Aagaard, D. Peretz, H.-O. B. Nguyen, C. Heinrich, M. Torchia, J. Safar, F. E. Cohen, S. J. DeArmond, S. B. Prusiner, and M. Scott, Cell 96:869-878, 1999). We removed additional sequences from PrP106 and identified a 61-residue peptide, designated PrP61, that spontaneously adopted a protease-resistant conformation in neuroblastoma cells. Synthetic PrP61 bearing a carboxy-terminal lipid moiety polymerized into protease-resistant, beta-sheet-enriched amyloid fibrils at a physiological salt concentration. Transgenic mice expressing low levels of PrP61 died spontaneously with ataxia. Neuropathological examination revealed accumulation of protease-resistant PrP61 within neuronal dendrites and cell bodies, apparently causing apoptosis. PrP61 may be a useful model for deciphering the mechanism by which PrP molecules acquire protease resistance and become neurotoxic.     

Evidence for a secretory form of the cellular prion protein

The biogenesis of hamster brain prion protein (PrP) has been studied by expression of RNA transcribed from a full-length PrP cDNA in Xenopus oocytes and cell-free systems. Earlier studies in the wheat germ cell-free system showed that one form of PrP is a transmembrane protein that spans the bilayer at least twice [Hay, B., Barry, R. A., Lieberburg, I., Prusiner, S. B., & Lingappa, V. R. (1987) Mol. Cell. Biol. 7, 914-920]. We now report that PrP can also exist as a secreted protein. SP6 PrP RNA microinjected into Xenopus oocytes produced two forms of PrP: one that remained in the cell and another that was secreted into the medium. Cell-free translation studies in rabbit reticulocyte lysates supplemented with microsomal membranes gave similar results: while one form of PrP was found as an integral membrane protein spanning the membrane at least twice, another form of PrP was found to be completely translocated to the microsomal membrane vesicle lumen. Both the membrane and secretory forms of PrP appear to be generated from the same pool of nascent chains. The mechanism governing the alternative fates of nascent PrP remains to be elucidated but may have significance for understanding the pathogenesis of scrapie and other prion diseases.     

A monomer-dimer equilibrium of a cellular prion protein (PrPC) not observed with recombinant PrP

Both the purified normal (protease-sensitive) isoform of the prion protein (PrP(C)) (Pergami, P., Jaffe, H., and Safar, J. (1996) Anal. Biochem. 236, 63-73) and recombinant prion protein (PrP) have been found to be in monomeric form (Mehlhorn, I., Groth, D., Stockel, J., Moffat, B., Reilly, D., Yansura, D., Willet, W. S., Baldwin, M., Fletterick, R., Cohen, F. E., Vandlen, R., Henner, D., and Prusiner, S. B. (1996) Biochemistry 35, 5528-5537; and this paper), and therefore PrP(C)-PrP(C) interactions were previously unknown. In this report we confirm recombinant PrP to be a monomer by analytical ultracentrifugation. However, by three lines of evidence (enzyme-linked immunosorbent assay (ELISA), cross-linking experiments, and size exclusion chromatography) we could also demonstrate that, under native conditions, at least part of the native bovine PrP(C) exists as a monomer-dimer equilibrium. A bovine PrP(C)-specific immuno-sandwich ELISA was developed and calibrated with recombinant PrP (Meyer, R. K., Oesch, B., Fatzer, R., Zurbriggen, A., and Vandevelde, M. (1999) J. Virol. 73, 9386-9392). By this ELISA we identified a distinct PrP(C) fraction and partially purified this protein. When serial dilutions of brain homogenate or partially purified PrP(C) were measured, using the peptide antibody C15S, a nonlinear dose-response curve was obtained. This nonlinearity was shown not to be due to an artifact of the procedure but to a monomer-dimer equilibrium of PrP(C) with preferential binding of the antibody to the dimer. From the curvature we could deduce the association constant (3.9 x 10(8) M(-1) at 37 degrees C). Accordingly, DeltaG degrees of the reaction was calculated (-48.6 kJ M(-1)), and DeltaH degrees (9.5 kJ M(-1)) as well as DeltaS degrees (0.2 kJ K(-1) M(-1)) were extrapolated from the van't Hoff plot. When serial dilutions of monomeric recombinant PrP were tested, only a straight line was obtained, supporting our hypothesis. Additional evidence of dimer formation was revealed by Western blotting of partially purified PrP(C) cross-linked by the homobifunctional cross-linker BS(3). Finally, size exclusion chromatography of partially purified PrP(C) fractions revealed an additional shoulder not observed with recombinant PrP. The difference in respect of dimer formation between native PrP(C) and recombinant PrP could be explained by the lack of glycosylation of the latter.     

Protease-sensitive scrapie prion protein in aggregates of heterogeneous sizes

The pathological prion protein PrP(Sc) is the only known component of the infectious prion. In cells infected with prions, PrP(Sc) is formed posttranslationally by the refolding of the benign cell surface glycoprotein PrP(C) into an aberrant conformation. The two PrP isoforms possess very different properties, as PrP(Sc) has a protease-resistant core, forms very large amyloidic aggregates in detergents, and is only weakly immunoreactive in its native form. We now show that prion-infected rodent brains and cultured cells contain previously unrecognized protease-sensitive PrP(Sc) varieties. In both ionic (Sarkosyl) and nonionic (n-octyl beta-D-glucopyranoside) detergents, the novel protease-sensitive PrP(Sc) species formed aggregates as small as 600 kDa, as measured by gel filtration. The denaturation dependence of PrP(Sc) immunoreactivity correlated with the size of the aggregate. The small PrP(Sc) aggregates described here are consistent with the previous demonstration of scrapie infectivity in brain fractions with a sedimentation coefficient as small as 40 S [Prusiner et al. (1980) J. Neurochem. 35, 574-582]. Our results demonstrate for the first time that prion-infected tissues contain protease-sensitive PrP(Sc) molecules that form low MW aggregates. Whether these new PrP(Sc) species play a role in the biogenesis or the pathogenesis of prions remains to be established.     

Calpain-dependent endoproteolytic cleavage of PrPSc modulates scrapie prion propagation

Previous studies using post-mortem human brain extracts demonstrated that PrP in Creutzfeldt-Jakob disease (CJD) brains is cleaved by a cellular protease to generate a C-terminal fragment, referred to as C2, which has the same molecular weight as PrP-(27-30), the protease-resistant core of PrP(Sc) (1). The role of this endoproteolytic cleavage of PrP in prion pathogenesis and the identity of the cellular protease responsible for production of the C2 cleavage product has not been explored. To address these issues we have taken a combination of pharmacological and genetic approaches using persistently infected scrapie mouse brain (SMB) cells. We confirm that production of C2 is the predominant cleavage event of PrP(Sc) in the brains of scrapie-infected mice and that SMB cells faithfully recapitulate the diverse intracellular proteolytic processing events of PrP(Sc) and PrP(C) observed in vivo. While increases in intracellular calcium (Ca(2+)) levels in prion-infected cell cultures stimulate the production of the PrP(Sc) cleavage product, pharmacological inhibitors of calpains and overexpression of the endogenous calpain inhibitor, calpastatin, prevent the production of C2. In contrast, inhibitors of lysosomal proteases, caspases, and the proteasome have no effect on C2 production in SMB cells. Calpain inhibition also prevents the accumulation of PrP(Sc) in SMB and persistently infected ScN2A cells, whereas bioassay of inhibitor-treated cell cultures demonstrates that calpain inhibition results in reduced prion titers compared with control-treated cultures assessed in parallel. Our observations suggest that calpain-mediated endoproteolytic cleavage of PrP(Sc) may be an important event in prion propagation.     

Differential effect of platelet-derived growth factor- versus serum-induced growth on smooth muscle alpha-actin and nonmuscle beta-actin mRNA expression in cultured rat aortic smooth muscle cells

Previous studies have demonstrated that rat aortic smooth muscle cells (SMC) show marked changes in smooth muscle (SM) alpha-actin content and fractional synthesis as a function of cell density and growth (Owens, G. K., Loeb, A., Gordon, D., and Thompson, M. M. (1986) J. Cell Biol. 102, 343-352; Blank, R., Thompson, M. M., and Owens, G. K. (1988) J. Cell Biol. 107, 299-306). Results of this study show that, although there is a 6-fold increase in SM alpha-actin content in postconfluent density arrested cultures as compared to proliferating subconfluent cultures, SM alpha-actin mRNA levels are not different between these cells. This suggests that the SM alpha-actin gene is constitutively active under both of these conditions and that accumulation of SM alpha-actin in postconfluent cells is due to translational and/or post-translational controls. The relationship between growth and cytodifferentiation was further explored by examining the effects of platelet-derived growth factor (PDGF)- or serum-induced growth on actin expression in postconfluent, quiescent cultures maintained in a defined serum-free media. Although both factors have been shown to stimulate proliferation and decrease fractional SM alpha-actin synthesis (Blank et al., 1988), their effects on actin mRNA levels were quite different. PDGF was found to induce a dramatic drop in SM alpha-actin steady state mRNA level but had no effect on nonmuscle beta-actin mRNA level. In contrast, serum stimulation was shown to increase nonmuscle beta-actin mRNA level, whereas SM alpha-actin mRNA level remained constant. Taken together these results indicate that PDGF is a specific and potent repressor of SM alpha-actin expression in vascular SMC and implicate a possible developmental role for PDGF in control of SMC differentiation. In addition, the observation that the level of SM alpha-actin mRNA is unaltered in serum-stimulated cells indicates that an absolute decrease in SM alpha-actin mRNA is not obligatory for cell cycle entrance.     

Synthetic fibril peptide promotes clearance of scrapie prion protein by lysosomal degradation

Transmissible spongiform encephalopathies are infectious and neurodegenerative disorders that cause neural deposition of aggregates of the disease-associated form of PrP(Sc). PrP(Sc) reproduces by recruiting and converting the cellular PrP(C), and ScN2a cells support PrP(Sc) propagation. We found that incubation of ScN2a cells with a fibril peptide named P9, which comprises an intrinsic sequence of residues 167-184 of mouse PrP(C), significantly reduced the amount of PrP(Sc) in 24 hr. P9 did not affect the rates of synthesis and degradation of PrP(C). Interestingly, immunofluorescence analysis showed that the incubation of ScN2a cells with P9 induced colocalization of the accumulation of PrP with cathepsin D-positive compartments, whereas the accumulation of PrP in the cells without P9 colocalized mainly with lysosomal associated membrane proteins (LAMP)-1-positive compartments but rarely with cathepsin D-positive compartments in perinuclear regions. Lysosomal enzyme inhibitors attenuated the anti-PrP(Sc) activity; however, a proteasome inhibitor did not impair P9 activity. In addition, P9 neither promoted the ubiquitination of cellular proteins nor caused the accumulation of LC3-II, a biochemical marker of autophagy. These results indicate that P9 promotes PrP(Sc) redistribution from late endosomes to lysosomes, thereby attaining PrP(Sc) degradation.     

Sialylation and sulfation of lactosylceramide distinctly regulate anchorage-independent growth,apoptosis, and gene expression in 3LL Lewis lung carcinoma cells

To investigate the significance of sialylation and sulfation of lactosylceramide in transformed cells, we established ganglioside GM3- and lactosylsulfatide (SM3)-reconstituted cells by transfecting cDNAs of GM3 synthase and cerebroside sulfotransferase into the J5 subclone of 3LL Lewis lung carcinoma cells. The J5 clone was selected for the transfection of these genes because it lacks GM3 and SM3 but accumulates lactosylceramide. The anchorage-dependent growth of both GM3- and SM3-reconstituted cells was similar. However, anchorage-independent growth (as measured by colony-forming ability in soft agar) of the SM3- reconstituted cells was almost completely lost, which supports our previous observation showing the suppression of tumorigenic potential in vivo and beta1 integrin gene expression induced by the introduction of cerebroside sulfotransferase gene (Kabayama et al. [2001] J. Biol. Chem., 276, 26777-26783). The GM3-reconstituted cells formed a significantly higher number of colonies in soft agar compared to mock-transfected cells and began to proliferate and become resistant to apoptosis when serum was depleted, indicating that endogenous GM3 is essential for maintaining these fundamental properties of malignant cells. We also found that serum-induced ERK1/2 activation was suppressed in the GM3-reconstituted cells, suggesting that anchorage-independent cell cycle initiation by endogenous GM3 is elicited through pathway(s) independent of ERK1/2 activation. The selective down-regulation of platelet-derived growth factor (PDGF)-dependent ERK1/2 activation in the GM3-reconstituted cells was due to the substantial decreases of PDGF alpha receptor mRNA and protein, but in the SM3-reconstituted cells PDGF alpha receptor expression was similar to mock cells. Thus, endogenously produced GM3 and SM3 differentially and distinctly regulate tumor-progression ability, that is, GM3 leads the transformed phenotype of J5 cells to promotion and SM3 to abrogation.     

Scrapie protein degradation by cysteine proteases in CD11c+ dendritic cells and GT1-1 neuronal cells

Dendritic cells (DC) of the CD11c(+) myeloid phenotype have been implicated in the spread of scrapie in the host. Previously, we have shown that CD11c(+) DC can cause a rapid degradation of proteinase K-resistant prion proteins (PrP(Sc)) in vitro, indicating a possible role of these cells in the clearance of PrP(Sc). To determine the mechanisms of PrP(Sc) degradation, CD11c(+) DC that had been exposed to PrP(Sc) derived from a neuronal cell line (GT1-1) infected with scrapie (ScGT1-1) were treated with a battery of protease inhibitors. Following treatment with the cysteine protease inhibitors (2S,3S)-trans-epoxysuccinyl-L-leucylamido-3-methylbutane (E-64c), its ethyl ester (E-64d), and leupeptin, the degradation of PrP(Sc) was inhibited, while inhibitors of serine and aspartic and metalloproteases (aprotinin, pepstatin, and phosphoramidon) had no effect. An endogenous degradation of PrP(Sc) in ScGT1-1 cells was revealed by inhibiting the expression of cellular PrP (PrP(C)) by RNA interference, and this degradation could also be inhibited by the cysteine protease inhibitors. Our data show that PrP(Sc) is proteolytically cleaved preferentially by cysteine proteases in both CD11c(+) DC and ScGT1-1 cells and that the degradation of PrP(Sc) by proteases is different from that of PrP(C). Interference by protease inhibitors with DC-induced processing of PrP(Sc) has the potential to modify prion spread, clearance, and immunization in a host.     

Modulation of proteinase K-resistant prion protein in cells and infectious brain homogenate by redox iron: implications for prion replication and disease pathogenesis

The principal infectious and pathogenic agent in all prion disorders is a beta-sheet-rich isoform of the cellular prion protein (PrP(C)) termed PrP-scrapie (PrP(Sc)). Once initiated, PrP(Sc) is self-replicating and toxic to neuronal cells, but the underlying mechanisms remain unclear. In this report, we demonstrate that PrP(C) binds iron and transforms to a PrP(Sc)-like form (*PrP(Sc)) when human neuroblastoma cells are exposed to an inorganic source of redox iron. The *PrP(Sc) thus generated is itself redox active, and it induces the transformation of additional PrP(C), simulating *PrP(Sc) propagation in the absence of brain-derived PrP(Sc). Moreover, limited depletion of iron from prion disease-affected human and mouse brain homogenates and scrapie-infected mouse neuroblastoma cells results in 4- to 10-fold reduction in proteinase K (PK)-resistant PrP(Sc), implicating redox iron in the generation, propagation, and stability of PK-resistant PrP(Sc). Furthermore, we demonstrate increased redox-active ferrous iron levels in prion disease-affected brains, suggesting that accumulation of PrP(Sc) is modulated by the combined effect of imbalance in brain iron homeostasis and the redox-active nature of PrP(Sc). These data provide information on the mechanism of replication and toxicity by PrP(Sc), and they evoke predictable and therapeutically amenable ways of modulating PrP(Sc) load.     

Modulation of prion protein oligomerization, aggregation, and beta-sheet conversion by 4,4'-dianilino-1,1'-binaphthyl-5,5'-sulfonate (bis-ANS)

The prion protein (PrP) is the major agent implicated in the diseases known as transmissible spongiform encephalopathies. The onset of transmissible spongiform encephalopathy is related to a change in conformation of the PrP(C), which loses most of its alpha-helical content, becoming a beta-sheet-rich protein, known as PrP(Sc). Here we have used two Syrian hamster prion domains (PrP 109-141 and PrP 109-149) and the murine recombinant PrP (rPrP 23-231) to investigate the effects of anilino-naphtalene compounds on prion oligomerization and aggregation. Aggregation in the presence of bis-ANS (4,4'-dianilino-1,1'-binaphthyl-5,5'-sulfonate), ANS (1-anilinonaphthalene-8-sulfonate), and AmNS (1-amino-5-naphtalenesulfonate) was monitored. Bis-ANS was the most effective inhibitor of prion peptide aggregation. Bis-ANS binds strongly to rPrP 23-231 leading to a substantial increase in beta-sheet content and to limited oligomerization. More strikingly, the binding of bis-ANS to full-length rPrP is diminished by the addition of nanomolar concentrations of oligonucleotides, demonstrating that they compete for the same binding site. Thus, bis-ANS displays properties similar to those of nucleic acids, causing oligomerization and conversion to beta-sheet (Cordeiro, Y., Machado, F., Juliano, L., Juliano, M. A., Brentani, R. R., Foguel, D., and Silva, J. L. (2001) J. Biol. Chem. 276, 49400-49409). This dual effect of bis-ANS on prion protein makes this compound highly important to sequester crucial conformations of the protein, which may be useful to the understanding of the disease and to serve as a lead for the development of new therapeutic strategies.     

Distinct immunohistochemical localization in Kuru plaques using novel anti-prion protein antibodies

By immunizing Prnp-knockout mice with synthetic polypeptides, a panel of mAbs directed to bovine PrP(C) was obtained. The mAb panel was characterized by the ELISA method, where synthetic polypeptides were used for epitope mapping. Different reactivity patterns were identified. The ability of these mAbs to detect abnormal PrP(Sc) in CJD cases was studied by immunohistochemistry. All mAbs were tested for PrP(Sc) in murine, bovine, monkey and human brain tissues. Three mAbs recognized the fragmented PrP epitope in our ELISA. Antibody 1D12 was strongly reactive to ovine and squirrel monkey tissues infected with a scrapie agent, although non-reactive to scrapie-infected mouse tissues. Antibody 2D8 was clearly reactive to type-2 but not type-1 CJD human tissues. Of particular interest was the reactivity of mAb 6C4 with the inner structure of Kuru plaques (peripheral pattern) in a type-2 CJD case and mAb T2, 1D12, 2B11, 2D8, 4B5 and 6G3-2 with the central area (central pattern). The fact that different anti-PrP mAbs possess distinct staining properties suggests that the PrP(c) to PrP(Sc) conversion might involve a multiple-step process.     

Site-specific characterization of the N-linked glycans of murine prion protein by high-performance liquid chromatography/electrospray mass spectrometry and exoglycosidase digestions

The murine prion protein PrP gene encodes a protein of 254 amino acids with two consensus sites for Asn-linked glycosylation at codons 180 and 196. A partial site-specific study of the N-linked glycans from hamster PrP has previously been carried out by mass spectrometry [Stahl, N., Baldwin, M. A., Teplow, D. B., Hood, L., Gibson, B. W., Burlingame, A. L., and Prusiner, S. B. (1993) Biochemistry 32, 1991-2002] and revealed that the glycosylation at Asn-181 (equivalent to mouse 180) is heterogeneous, comprising over 30 glycoforms. The identification of the glycosylated peptide spanning Asn-197 was not reported. Recent technical advances in electrospray mass spectrometry now provide the sensitivity to detect low femtomole quantities of glycopeptides with >5000 mass resolution and 30 ppm mass measurement [Medzihradszky, K. F., Besman, M. J., and Burlingame, A. L. (1998) Rapid Commun. Mass Spectrom. 12, 472-478]. This performance coupled with stepwise exoglycosidase digestion has been employed to establish the differential nature of the structural complexity (glycoforms) of the glycans at Asn-180 and Asn-196 from a single strain infected with the ME7 strain. Some sixty structures have been found characterized by neutral and sialylated bi-, tri-, and tetraantennary complex-type bearing outer-arm alpha(1-3)-fucosylation (the Lewisx and sialyl-Lewisx epitopes), core alpha(1,6) fucosylation, and the presence of terminal HexNAc residues. The Lewisx trisaccharide is the major nonreducing structure at Asn-180, and significant amounts of both Lewisx and sialyl Lewisx epitopes are observed at Asn-196. The abundance of the Lewisx and sialyl Lewisx epitopes on murine PrPSc may indicate a role for these structures in the normal function of PrPC or the pathophysiology of PrPSc.     

The charge structure of helix 1 in the prion protein regulates conversion to pathogenic PrPSc

The prion diseases are transmissible neurodegenerative disorders linked to a pathogenic conformer (PrP(Sc)) of the normal prion protein (PrP(C)). Accumulation of PrP(Sc) occurs via a poorly defined process in which PrP(Sc) complexes with and converts endogenous PrP(C) to nascent PrP(Sc). Recent experiments have focused on the highly charged first alpha helix (H1) of PrP. It has been proposed that two putative asparagine-to-arginine intrahelical salt bridges stabilize H1 in PrP(C) yet form intermolecular ionic bonds with adjacent PrP molecules during conversion of PrP(C) to PrP(Sc) (M. P. Morrissey and E. I. Shakhnovich, Proc. Natl. Acad. Sci. USA 96:11293-11298, 1999). Subsequent work (J. O. Speare et al., J. Biol. Chem. 278:12522-12529, 2003 using a cell-free assay of PrP(Sc) conversion suggested that rather than promoting conversion, the salt bridges stabilize PrP(C) against it. However, the role of individual H1 charges in PrP(Sc) generation has not yet been investigated. To approach this question, we systematically reversed or neutralized each charged residue in H1 and tested the effect on conversion to PrP(Sc) in scrapie-infected murine neuroblastoma (ScN2a) cells. We find that replacements of charged H1 residues with like charges permit conversion, while charge reversals hinder it. Neutralization of charges in the N-terminal (amino acids 143 to 146) but not the C-terminal (amino acids 147 to 151) half of H1 permits conversion, while complete reversal of charge orientation of the putative salt bridges produces a nonconvertible PrP. Circular dichroism spectroscopy studies and confocal microscopy immunofluorescence localization studies indicated that charge substitutions did not alter the secondary structure or cell surface expression of PrP(C). These data support the necessity of specific charge orientations in H1 for a productive PrP(Sc)-PrP(C) complex.     

Two mammalian longevity assurance gene (LAG1) family members,trh1 and trh4, regulate dihydroceramide synthesis using different fatty acyl-CoA donors

Overexpression of upstream of growth and differentiation factor 1 (uog1), a mammalian homolog of the yeast longevity assurance gene (LAG1), selectively induces the synthesis of stearoyl-containing sphingolipids in mammalian cells (Venkataraman, K., Riebeling, C., Bodennec, J., Riezman, H., Allegood, J. C., Sullards, M. C., Merrill, A. H. Jr., and Futerman, A. H. (2002) J. Biol. Chem. 277, 35642-35649). Gene data base analysis subsequently revealed a new subfamily of proteins containing the Lag1p motif, previously characterized as translocating chain-associating membrane (TRAM) protein homologs (TRH). We now report that two additional members of this family regulate the synthesis of (dihydro)ceramides with specific fatty acid(s) when overexpressed in human embryonic kidney 293T cells. TRH1 or TRH4-overexpression elevated [3H](dihydro)ceramide synthesis from l-[3-3H]serine and the increase was not blocked by the (dihydro)ceramide synthase inhibitor, fumonisin B1 (FB1). Analysis of sphingolipids by liquid chromatography-electrospray tandem mass spectrometry revealed that TRH4 overexpression elevated mainly palmitic acid-containing sphingolipids whereas TRH1 overexpression increased mainly stearic acid and arachidic acid, which in both cases were further elevated upon incubation with FB1. A similar fatty acid specificity was obtained upon analysis of (dihydro)ceramide synthase activity in vitro using various fatty acyl-CoA substrates, although in a FB1-sensitive manner. Moreover, in homogenates from TRH4-overexpressing cells, sphinganine, rather than sphingosine was the preferred substrate, whereas no preference was seen in homogenates from TRH1-overexpressing cells. These findings lend support to our hypothesis (Venkataraman, K., and Futerman, A. H. (2002) FEBS Lett. 528, 3-4) that Lag1p family members regulate (dihydro)ceramide synthases responsible for production of sphingolipids containing different fatty acids.     

Heparan sulfate is a cellular receptor for purified infectious prions

Prions replicate in the host cell by the self-propagating refolding of the normal cell surface protein, PrP(C), into a beta-sheet-rich conformer, PrP(Sc). Exposure of cells to prion-infected material and subsequent endocytosis can sometimes result in the establishment of an infected culture. However, the relevant cell surface receptors have remained unknown. We have previously shown that cellular heparan sulfates (HS) are involved in the ongoing formation of scrapie prion protein (PrP(Sc)) in chronically infected cells. Here we studied the initial steps in the internalization of prions and in the infection of cells. Purified prion "rods" are arguably the purest prion preparation available. The only proteinaceous component of rods is PrP(Sc). Mouse neuroblastoma N2a, hypothalamus GT1-1, and Chinese hamster ovary cells efficiently bound both hamster and mouse prion rods (at 4 degrees C) and internalized them (at 37 degrees C). Treating cells with bacterial heparinase III or chlorate (a general inhibitor of sulfation) strongly reduced both binding and uptake of rods, whereas chondroitinase ABC was inactive. These results suggested that the cell surface receptor of prion rods involves sulfated HS chains. Sulfated glycans inhibited both binding and uptake of rods, probably by competing with the binding of rods to cellular HS. Treatments that prevented endocytosis of rods also prevented the de novo infection of GT1-1 cells when applied during their initial exposure to prions. These results indicate that HS are an essential part of the cellular receptor used both for prion uptake and for cell infection. Cellular HS thus play a dual role in prion propagation, both as a cofactor for PrP(Sc) synthesis and as a receptor for productive prion uptake.