Subcellular localization of prion proteins and the 37 kDa/67 kDa laminin receptor fused to fluorescent proteins.

The 37 kDa/67 kDa laminin receptor LRP/LR acts as a receptor for both PrPc and PrPSc at the cell surface. Here, we further analyzed the subcellular localization of fluorescent labeled prion protein (PrP) and laminin receptor (LRP/LR) molecules. We show that EGFP-PrP is localized at the cell surface and in a perinuclear compartment, respectively. In contrast, a DsRed-DeltaSP-PrP mutant lacking the signal peptide is almost exclusively found in the nucleus but does not colocalize with heterochromatin. Interestingly, LRP-DsRed efficiently colocalizes with EGFP-PrP in the perinuclear compartment and LRP-ECFP partly colocalizes with DsRed-DeltaSP-PrP in the nucleus, respectively. We conclude that the interactions of PrP and LRP/LR are not restricted to the cell surface but occur also in intracellular compartments suggesting a putative role of LRP/LR in the trafficking of PrP molecules.

The 37-kDa/67-kDa laminin receptor acts as a receptor for infectious prions and is inhibited by polysulfated glycanes.

BACKGROUND: Recently, we showed that the 37-kDa/67-kDa laminin receptor (LRP/LR) acts as the receptor of the cellular prion protein. METHODS: For the present study, we investigated the binding of the murine scrapie prion protein (moPrP27-30) to baby hamster kidney (BHK) cells, using the Semliki Forest virus system. RESULTS: The enhanced binding of moPrP27-30 to BHK cells expressing moLRP::FLAG was inhibited by the LRP/LR-specific antibody W3, which suggests that LRP/LR acts as a receptor for the scrapie form of the prion protein, PrP(Sc). This finding was confirmed by a parallel study that showed that bovine prions are internalized by human enterocytes via LRP/LR. The heparan sulfate mimetics HM5004 and HM2602 reduced PrP27-30 binding to moLRP-expressing cells to approximately 30% and approximately 20%, respectively, at a concentration of 10 microg/mL, whereas pentosan polysulfate (SP54) and phycarin sulfate (PS3) both reduced the binding to approximately 40% at a concentration of 100 microg/mL. CONCLUSIONS: We suggest that the inhibition reported elsewhere of PrP(Sc) synthesis and the incubation times prolonged in rodent models by these sulfated glycans are due to the inhibition of the LRP/LR-dependent binding of prions to the target cells.

Bovine prion is endocytosed by human enterocytes via the 37 kDa/67 kDa laminin receptor.

Some forms of transmissible spongiform encephalopathies result from oral infection. We have thus analyzed the early mechanisms that could account for an uptake of infectious prion particles by enterocytes, the major cell population of the intestinal epithelium. Human Caco-2/TC7 enterocytes cultured on microporous filters were incubated with different prion strains and contaminated brain homogenates in the apical compartment. Internalization of infectious particles was analyzed by Western blotting and immunofluorescence. We observed internalization by enterocytes of prion particles from bovine spongiform encephalopathy brain homogenates but not from mouse-adapted scrapie-strain brain homogenates or purified bovine spongiform encephalopathy scrapie-associated fibrils. Bovine prion particles were internalized via endocytosis within minutes of infection and were associated with subapical vesicular structures related to early endosomes. The endocytosis of the infectious bovine PrP(Sc) was reduced by preincubating the cells with an anti-LRP/LR blocking antibody, identifying the 37 kDa/67 kDa laminin receptor (LRP/LR), which is apically expressed in Caco-2/TC7 cells, as the receptor for the infectious prion protein. Altogether, our results underscore a potential role of enterocytes in the absorption of bovine prions during oral infection through specific LRP/LR-dependent endocytosis.

Intra- and interspecies interactions between prion proteins and effects of mutations and polymorphisms.

Recently, crystallization of the prion protein in a dimeric form was reported. Here we show that native soluble homogeneous FLAG-tagged prion proteins from hamster, man and cattle expressed in the baculovirus system are predominantly dimeric. The PrP/PrP interaction was confirmed in Semliki Forest virus-RNA transfected BHK cells co-expressing FLAG- and oligohistidine-tagged human PrP. The yeast two-hybrid system identified the octarepeat region and the C-terminal structured domain (aa90-aa230) of PrP as PrP/PrP interaction domains. Additional octarepeats identified in patients suffering from fCJD reduced (wtPrP versus PrP + 9OR) and completely abolished (PrP + 9OR versus PrP + 9OR) the PrP/PrP interaction in the yeast two-hybrid system. In contrast, the Met/Val polymorphism (aa129), the GSS mutation Pro102Leu and the FFI mutation Asp178Asn did not affect PrP/PrP interactions. Proof of interactions between human or sheep and bovine PrP, and sheep and human PrP, as well as lack of interactions between human or bovine PrP and hamster PrP suggest that interspecies PrP interaction studies in the yeast two-hybrid system may serve as a rapid pre-assay to investigate species barriers in prion diseases.

Recombinant human prion protein mutants huPrP D178N/M129 (FFI) and huPrP+9OR (fCJD) reveal proteinase K resistance.

The Semliki-Forest virus (SFV) system was used to overexpress human wild-type and mutant prion proteins as well as FLAG-tagged human and bovine PrP in mammalian cells. The application of recombinant SFV vectors allowed a high-level production of highly glycosylated prion proteins with a molecular weight ranging from 25 to 30 kDa for recombinant wild-type human PrP and from 26 to 32 kDa for wild-type bovine PrP. Further, we report here the generation of recombinant mutant prion proteins that are associated with inherited human prion diseases such as fatal familial insomnia (FFI) and Creutzfeldt-Jakob disease (CJD). Both mutated variants, the FFI-associated PrP carrying a mutation at amino acid position 178 and the CJD-linked form containing an insertion of nine additional octarepeats reveal proteinase K resistance, one of the typical biochemical properties of the infectious scrapie isoform of the prion protein. By contrast, recombinant wild-type PrP was completely proteinase K sensitive when expressed in SFV-transfected BHK cells. The subcellular location of both PrP mutants at the cell surface and in intracellular compartments of transfected BHK cells was similar to that of wild-type PrP. In order to purify recombinant human and bovine PrP from cell lysates, a FLAG-tag was introduced either at the N-terminus behind the signal peptide or at the C-terminus close to the adhesion site of the GPI anchor. N-terminal insertion did not extensively influence the trafficking of the FLAG-tagged protein to the cell surface, whereas insertion close to the GPI attachment site clearly affected the transport of the majority of PrP to the cell membrane, probably resulting in their retention within the secretory pathway. All FLAG-tagged prion proteins were expressed efficiently in BHK cells and showed a typical glycosylation pattern, allowing their rapid and simple purification via anti-FLAG antibody chromatography.

High-level expression and characterization of a glycosylated covalently linked dimer of the prion protein.

There is evidence that prion protein dimers may be involved in the formation of the scrapie prion protein, PrP(Sc), from its normal (cellular) form, PrP(c). Recently, the crystal structure of the human prion protein in a dimeric form was reported. Here we report for the first time the overexpression of a human PrP dimer covalently linked by a FLAG peptide (PrP::FLAG::PrP) in the methylotrophic yeast Pichia pastoris. FLAG-tagged human PrP (aa1-aa253) (huPrP::FLAG) was also expressed in the same system. Treatment with tunicamycin and endoglycosidase H showed that both fusion proteins are expressed as various glycoforms. Both PrP proteins were completely digested by proteinase K (PK), suggesting that the proteins do not have a PrP(Sc) structure and are not infectious. Plasma membrane fractionation revealed that both proteins are transported to the plasma membrane of the cell. The glycosylated proteins might act as powerful tools for crystallization trials, PrP(c)/PrP(Sc) conversion studies and other applications in the life cycle of prions.