Cell-surface retention of PrPC by anti-PrP antibody prevents protease-resistant PrP formation

Chan-Lan Kim1, Ayako Karino1, Naotaka Ishiguro1, Morikazu Shinagawa1,{dagger}, Motoyoshi Sato2 and Motohiro Horiuchi1,{ddagger}

1 Laboratory of Veterinary Public Health, Obihiro University of Agriculture and Veterinary Medicine, Inada-cho, Obihiro, Hokkaido 080-8555, Japan
2 Laboratory of Veterinary Radiology, Obihiro University of Agriculture and Veterinary Medicine, Inada-cho, Obihiro, Hokkaido 080-8555, Japan

Correspondence
Motohiro Horiuchi
horiuchi{at}vetmed.hokudai.ac.jp


   ABSTRACT
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
The C-terminal portion of the prion protein (PrP), corresponding to a protease-resistant core fragment of the abnormal isoform of the prion protein (PrPSc), is essential for prion propagation. Antibodies to the C-terminal portion of PrP are known to inhibit PrPSc accumulation in cells persistently infected with prions. Here it was shown that, in addition to monoclonal antibodies (mAbs) to the C-terminal portion of PrP, a mAb recognizing the octapeptide repeat region in the N-terminal part of PrP that is dispensable for PrPSc formation reduced PrPSc accumulation in cells persistently infected with prions. The 50 % effective dose was as low as ~1 nM, and, regardless of their epitope specificity, the inhibitory mAbs shared the ability to bind cellular prion protein (PrPC) expressed on the cell surface. Flow cytometric analysis revealed that mAbs that bound to the cell surface during cell culture were not internalized even after their withdrawal from the growth medium. Retention of the mAb–PrPC complex on the cell surface was also confirmed by the fact that internalization was enhanced by treatment of cells with dextran sulfate. These results suggested that anti-PrP mAb antagonizes PrPSc formation by interfering with the regular PrPC degradation pathway.

{dagger}Present address: Prion Disease Research Center, National Institute of Animal Health, Kannondai, Tsukuba, Ibaragi, 305-0856, Japan.

{ddagger}Present address: Laboratory of Prion Diseases, Graduate School of Veterinary Medicine, Hokkaido University, Kita 18, Nishi 9, Kita-ku, Sapporo 060-0818, Japan.


   INTRODUCTION
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Transmissible spongiform encephalopathies (TSEs), also called prion diseases, are fatal neurodegenerative diseases and include scrapie in sheep and goats, bovine spongiform encephalopathy and Creutzfeldt–Jakob disease (CJD) in humans. The causative agent of TSEs, often called a prion, is composed mainly of an abnormal isoform (PrPSc) of the host cellular prion protein (PrPC). Mice with genetic knockout of the PrP gene are resistant to prion disease (Bueler et al., 1993) and neurons lacking PrPC expression are resistant to degeneration, regardless of the presence of PrPSc (Mallucci et al., 2003). Thus, PrPC is essential for prion propagation and pathogenesis.

Conversion of PrPC to PrPSc is believed to involve direct interaction of the two PrP isoforms. Although the molecular mechanism of conversion is not yet fully understood, it is known that mature PrPC expressed on the cell surface is a substrate for PrPSc formation, and a process that involves a conformational transformation takes place in subcellular compartments associated with the degradation pathway of PrPC, including a sphingolipid-rich membrane microdomain, called a lipid raft (Caughey & Raymond, 1991; Naslavsky et al., 1997; Vey et al., 1996).

Because of the emergence of variant CJD and iatrogenic CJD by dura matter transplantation, especially in Japan, the establishment of therapeutics for prion disease is urgently needed. Therapeutics have been directed at the binding of the two PrP isoforms, as well as the process of conformational transformation, since the conversion of PrPC to PrPSc is associated with neuronal pathogenicity. To date, many substances have been reported to inhibit PrPSc formation in cell culture and/or cell-free systems, including amyloid-binding dyes (Caughey & Race, 1992), sulfated glycosaminoglycans (Caughey & Raymond, 1993), tetrapyrrole compounds (Caughey et al., 1998), cysteine protease inhibitors (Doh-Ura et al., 2000), substituted tricyclic derivatives such as chlorpromazine and quinacrine (Doh-Ura et al., 2000; Korth et al., 2001), branched polyamines (Supattapone et al., 1999, 2001), peptides (Chabry et al., 1998; Soto et al., 2000) and conversion-incompetent PrP (Holscher et al., 1998; Horiuchi et al., 2000; Kaneko et al., 1997). Some of these have already been examined in vivo. For instance, sulfated glycosaminoglycans and tetrapyrrole compounds were effective when administered at early stages of infection or simultaneously with the scrapie-affected brain inoculum (Ehlers & Diringer, 1984; Ladogana et al., 1992; Priola et al., 2000). Polyene antibiotics prolonged the incubation period, even when administered at the middle-late stage of infection (Demaimay et al., 1997), but the effects appeared to depend on the prion strains and host animals studied (Demaimay et al., 1999; Xi et al., 1992). Recently, Doh-Ura and colleagues (2004) showed that intraventricular administration of pentosan polysulfate and quinine prolonged the incubation periods in a prion-infected transgenic mouse model, even at a late stage of infection (Doh-Ura et al., 2004; Murakami-Kubo et al., 2004). Further in vivo studies are expected to lead to the establishment of effective therapeutics for prion diseases. However, to achieve more efficient therapeutics, it is essential to elucidate the mechanisms of action and to investigate proper delivery of drugs based on pharmacokinetics.

Anti-PrP antibodies have also been reported to inhibit the formation of PrPSc in cultured cells and/or cell-free systems (Enari et al., 2001; Horiuchi & Caughey, 1999; Kaneko et al., 1995; Peretz et al., 2001). Transgenic mice expressing an anti-PrP mAb on B cells (Heppner et al., 2001), immunization with recombinant PrP (Sigurdsson et al., 2002) and passive immunization with an anti-PrP mAb (White et al., 2003) antagonized the peripheral inoculation of scrapie-affected brain inoculum. These in vivo experiments suggested the possible use of anti-PrP antibodies as a therapy for prion diseases. However, it remains unclear how anti-PrP antibodies can antagonize PrPSc formation in cells. To address this point, in the current study, we evaluated a panel of anti-PrP mAbs against diverse epitopes for inhibition of PrPSc formation. We found that a mAb recognizing the octapeptide repeat sequence, a region that is not essential for PrPSc formation, reduced PrPSc accumulation in cells persistently infected with prions. Furthermore, our data suggest a possible link between cell-surface retention of PrPC by anti-PrP antibodies and inhibition of PrPSc formation in cells.


   METHODS
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Antibodies and chemicals.
The properties of anti-PrP mAbs used in this study have been described elsewhere (Kim et al., 2004). The mAb against sarcomeric actin (clone alpha-Sr-1) was purchased from DAKO. Stock solutions of chlorpromazine, dextran sulfate 500 (DS500) and polyethyleneimine were prepared in deionized water, while E-64d was dissolved in DMSO and quinacrine in methanol. Culture medium containing each chemical compound or mAb was prepared freshly for each experiment.

Cell culture.
The mouse neuroblastoma cell line Neuro2a (CCL-131; ATCC) was cultured in Dulbecco's modified Eagle's medium (ICN Biomedicals) with 10 % fetal bovine serum (FBS) and non-essential amino acids. Mouse neuroblastoma cells persistently infected with prions, originally established by Race et al. (1987), were cloned by limiting dilution. Subclone I3/I5-9, which possessed a high level of PrPSc, was used in this study. I3/I5-9 cells were maintained in Opti-MEM (Invitrogen) containing 10 % FBS and cells passaged fewer than 20 times were used for experiments.

Treatment of cells persistently infected with prions and sample preparation.
Almost-confluent I3/I5-9 cells in 25 cm2 flasks were split 1 : 20 into 35 mm tissue culture dishes. On day 2, the medium was replaced with 3 ml Opti-MEM containing 4 % FBS and each test compound or mAb, and the cells were cultured for a further 3 days. For PrPC detection, the cells were washed with PBS and lysed with 300 µl lysis buffer A (1 % Zwittergent 3-14, 150 mM NaCl, 50 mM Tris/HCl, pH 7·5) supplemented with protease inhibitors (2 mM EDTA, 1 µg pepstatin ml–1, 2 µg leupeptin ml–1, 2 µM bestatin and 1 µg aprotinin ml–1). After the removal of cell debris by low-speed centrifugation, samples were centrifuged at 45 000 r.p.m. for 30 min at 4 °C using the TLA 100.3 rotor of a Beckman Optima TLX and the resulting supernatants were used as a source of PrPC. For the detection of PrPSc, cells were lysed with 300 µl lysis buffer B (5 mM EDTA, 0·5 % Triton X-100, 0·5 % sodium deoxycholate, 150 mM NaCl, 10 mM Tris/HCl, pH 7·5) and kept on ice for 30 min. Cell debris was removed by centrifugation for 5 min at 1000 r.p.m. A portion of the sample (10 %) was removed for determination of protein concentration using the DC protein assay (Bio-Rad) and the remaining portions were treated with 20 µg proteinase K ml–1 for 20 min at 37 °C. Proteolysis was terminated by the addition of 1 mM Pefabloc (Roche). The samples were then treated with DNase I (100 µg ml–1) and RNase A (5 µg ml–1) for 15 min at room temperature and centrifuged at 70 000 r.p.m. for 2 h at 4 °C using the TLA 100.3 rotor of a Beckman Optima TLX. The resulting pellets were dissolved in SDS-PAGE sample buffer.

SDS-PAGE and immunoblotting.
SDS-PAGE was carried out using NuPAGE 12 % Bis-tris gels and MOPS-SDS running buffer according to the manufacturer's instructions (Invitrogen). After SDS-PAGE, proteins were transferred on to Immobilon-P PVDF membranes (Millipore) using a Transblot Mini Cell wet-type blotting apparatus (Bio-Rad) and NuPAGE transfer buffer (Invitrogen) at 60 V for 2 h. Immunoreactive proteins were detected using X-ray film as described elsewhere (Kim et al., 2004). For quantitative analysis, immunoreactive proteins were visualized using the Western-Star Protein detection kit (TROPIX) according to the supplier's instructions and processed with an LAS-1000 lumino image analyser (Fujifilm). The intensity of the bands was quantified using Science Lab 98 Image Gauge software (Fujifilm).

Flow cytometric analysis.
Adherent cells were treated with ice-cold PBS containing 0·1 % collagenase (Wako) and dispersed by pipetting. Cells were washed with 0·5 % FBS in PBS (FBS/PBS) and incubated with anti-PrP mAbs diluted with 0·5 % FBS/PBS for 30 min on ice. Cells were washed three times with 0·5 % FBS/PBS and incubated with 1 : 2000-diluted Alexa 488-labelled Fab fragment of goat anti-mouse IgG (Molecular Probes) for 30 min. After washing, cells were stained with 5 µg propidium iodide ml–1 in 0·5 % FBS/PBS for 5 min and analysed using an EPICS XL-ADC flow cytometer (Beckman Coulter). All procedures were carefully carried out under chilled conditions.

Indirect immunofluorescence assay.
Cells grown in eight-well slides (Nunc) were fixed with 100 % methanol for 20 min at –20 °C. Fixed cells were blocked with 5 % FBS/PBS for 30 min at room temperature, after which they were incubated with hybridoma supernatants or mAbs diluted in 1 % FBS/PBS for 30 min at room temperature. After washing with PBS, cells were incubated with 1 : 1000-diluted Alexa 488-labelled Fab fragment of goat anti-mouse IgG for 30 min. Finally, the slides were mounted with PBS containing 50 % glycerol and 1 % n-propyl gallate (Wako) and examined using a fluorescence microscope equipped with a cooled CCD unit (CoolSNAP HQ; Roper).

Cell growth and cytotoxicity.
The effect of mAbs on cell growth was analysed using the 4-[3-(4-iodophenyl)-2-(4-nitrophenyl)-2H-5-tetrazolio]-1,3-benzene disulfonate (WST-1) assay (Ishiyama et al., 1996) and cytotoxicity was analysed by lactate dehydrogenase (LDH) release assay using the LDH-Cytotoxic Test (Wako).


   RESULTS
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Anti-PrP mAbs inhibit PrPSc accumulation in cultured cells
Several antibodies recognizing regions in the C-terminal portion of PrP have been reported to inhibit PrPSc accumulation in neuroblastoma cells persistently infected with prions (Enari et al., 2001; Peretz et al., 2001). We recently established a panel of diverse anti-PrP mAbs including those recognizing the octapeptide repeat in the N-terminal region of PrP (Kim et al., 2004). In the current studies, we investigated whether they would effect PrPSc accumulation in prion-infected neuroblastoma cells. Fig. 1(a) shows the effect of mAbs recognizing linear epitopes on PrPSc accumulation in I3/I5-9 cells persistently infected with prions. Following a 3-day treatment, only two mAbs reduced PrPSc accumulation: 31C6, which recognizes aa 143–149 of mouse PrP, and 110, which recognizes PHGGGWG at aa 59–65 and aa 83–89 in the octapeptide repeat. Quantitative analysis revealed that other mAbs did not affect the total amount of PrPSc, or the ratio of di-, mono- and non-glycosylated PrPSc.



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Fig. 1. Inhibition of PrPSc accumulation in prion-infected I3/I5-9 cells by anti-PrP mAbs. (a) Detection of PrPSc (upper panels) and PrPC (lower panels). I3/I5-9 cells were cultured for 3 days with 4 % FBS in Opti-MEM containing 5 µg mAbs ml–1. The level of PrPSc in the cells was determined by immunoblot analysis using mAb 44B1. Antibodies added to the culture are indicated above the panels. mAb P1-284 against feline panleukopenia virus was used as a control for non-specific effects. For detection of PrPSc, the load volume of each sample was adjusted based on the protein concentration of the corresponding cell lysate that had not been treated with proteinase K. For quantitative analysis of PrPSc, the three PrPSc bands indicated by a square bracket (right-hand side, upper panels) were grouped together. To check the ratios of the three PrPSc bands, each was selected separately. For PrPC, the PrPC bands indicated by a square bracket (right-hand side, lower panels) were quantified. The bands indicated by the arrowhead were excluded from the quantitative analysis, as they overlapped with immunoglobulin light chains that were detected by secondary antibodies. The blot used for PrPC detection was also probed with anti-sarcomeric actin mAb for normalization. The levels of PrPSc and PrPC relative to cells treated with negative-control mAb (P1-284) are indicated below the panels. NT, cells cultured without mAbs. Molecular mass markers are shown in kDa on the left. Epitopes for mAbs were as follows: 110, aa 56–89; 132, aa 119–127; 118, aa 137–143; 31C6, aa 143–149; 149, aa 147–151; 147, aa 219–229 (Kim et al., 2004). (b) Binding of mAbs to the surface of Neuro2a cells examined by flow cytometry. The left panel shows mAbs that bound to the cell surface, while the right panel shows mAbs that did not bind. mAb P1-284 was used as a control for non-specific binding.

 
Flow cytometric analysis showed that mAbs 110 and 31C6 bound PrPC on the cell surface, although the fluorescence intensity of mAb 110 was weaker than that of mAb 31C6 (Fig. 1b, left panel). In contrast, mAbs that had no effect on PrPSc accumulation did not appear to bind to PrPC on the cell surface (Fig. 1b, right panel). Two other mAbs, 44B1 and 72, which are thought to recognize discontinuous epitopes (Kim et al., 2004), reacted with PrPC on the cell surface (Fig. 1b) and inhibited PrPSc accumulation (Fig. 2). These results suggested that mAbs that can bind to PrPC on the cell surface have the potential to antagonize PrPSc accumulation in cells persistently infected with prions.



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Fig. 2. Dose-dependent inhibition of PrPSc accumulation by anti-PrP mAbs. (a) Representative results from immunoblotting. I3/I5-9 cells were cultured for 3 days with various concentrations of mAb as indicated above the panels. The level of PrPSc was determined by immunoblot analysis using mAb 44B1. (b) Dose-response curve. The intensity of the PrPSc bands in the blots was quantified using an LAS-1000 lumino image analyser. The PrPSc level in the absence of mAbs was assigned a value of 100 % in each experiment. The graph shows means±SD from at least three independent experiments. EC50 values were estimated using GraphPad PRISM (GraphPad Software).

 
Fig. 2 shows the dose-dependence of the effect of the anti-PrP mAbs. The four effective mAbs (110, 31C6, 44B1 and 72) reduced the amount of PrPSc in a dose-dependent manner, although PrPSc was not completely eliminated following the 3-day treatment. The 50 % effective dose (EC50) of mAbs 110, 31C6, 44B1 and 72 was estimated to be 0·2 µg ml–1(1·2 nM), 0·1 µg ml–1 (0·7 nM), 0·3 µg ml–1 (1·7 nM) and 0·6 µg ml–1 (4·1 nM), respectively (Fig. 2b).

Fig. 3 shows the long-term effect of mAbs on PrPSc formation. Treatment for 6 days with mAb 110, 44B1, 31C6 (Fig. 3) or 72 (data not shown) reduced PrPSc to an almost undetectable level, and no re-emergence of PrPSc was observed in the following 6 and 12 days of incubation in the absence of mAbs. On the contrary, mAbs that did not bind to cell-surface PrPC showed little effect on PrPSc accumulation even after long-term treatment.



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Fig. 3. Clearance of PrPSc by long-term antibody treatment. I3/I5-9 cells were cultured for 6 days with 5 µg mAb ml–1 (top panels). After withdrawal of the mAb, cells were cultured for an additional 6 (middle panels) or 12 (bottom panels) days in the absence of mAb. Quantitative analysis was carried out as described in the legend to Fig. 1 and relative PrPSc (left panels) and PrPC (right panels) levels are indicated below the corresponding images.

 
The influence of mAbs on cell growth and acute toxicity was examined by WST-1 assay and LDH release assay, respectively. No significant effect on cell growth was observed, even with long-term treatment (5 µg ml–1 for 6 days) and mAbs did not demonstrate any acute toxicity (10 µg ml–1) following 2 h of treatment.

Effect of anti-PrP mAbs on total amount of PrPC
Fig. 1(a, lower panel) shows total PrPC in the I3/I5-9 cells treated with mAbs for 3 days. The intensities of PrPC bands were normalized with {alpha}-sarcomeric actin on the same blot and PrPC levels relative to cells treated with negative control mAb (P1-284) are indicated at the bottom. Although there was a certain degree of variation, no marked difference was observed in the total amount of PrPC. In contrast, after long-term treatment (6 days), the total amount of PrPC in I3/I5-9 cells treated with mAb 110 or 44B1 appeared to be higher than that with the negative-control mAb or other anti-PrP mAbs (Fig. 3, top right panel). To confirm this further, we repeated the same experiment at least three times for the four inhibitory mAbs, 110, 31C6, 44B1 and 72. Relative PrPC levels in cells treated with these four mAbs were 168±38, 88±23, 183±54 and 103±33 %, respectively. These results suggested that the effect of mAbs on PrPC level varied depending on the mAb: mAbs 110 and 44B1 increased total PrPC levels following long-term treatment, while mAbs 31C6 and 72 did not affect the total PrPC level.

Cell-surface localization of the mAb–PrPC complex
The N-terminal portion of PrP, including the octapeptide repeat, is not essential for PrPSc formation and/or prion propagation (Flechsig et al., 2000; Rogers et al., 1993). The finding that not only the mAbs recognizing the C-terminal part of PrP, such as 31C6 and 44B1, but also mAb 110 inhibited PrPSc accumulation in the neuroblastoma cells, together with the fact that only the mAbs that bound to cell-surface PrPC showed an inhibitory effect, implied that the mAb–PrPC interaction on the cell surface is essential for inhibition of PrPSc accumulation. To investigate this further, we analysed the dynamics of anti-PrP mAbs after their binding to the cell surface (Fig. 4). Neuro2a cells were treated with 10 µg mAb 31C6 ml–1 for 1 h, after which the cells were cultured for an additional 4 h without mAb. Cells were then harvested and stained with an Alexa 488-conjugated secondary antibody. As a control, cells cultured with mAb 31C6 for 1 h were immediately stained with the secondary antibody. Flow cytometric analysis showed no difference in fluorescence intensity between the two preparations, suggesting that the mAb–PrPC complex remained on the cell surface, even after the additional 4 h culture in the absence of mAb. As I3/I5-9 cells are established by repeated limiting dilution, Neuro2a cells may not be a suitable uninfected control for I3/I5-9 cells. Hence, we carried out the same experiment using I3/I5-9 cells. It is known that elimination of PrPSc parallels the reduction of prion infectivity. Considering biosafety issues, we used I3/I5-9 cells cured of PrPSc by long-term treatment with mAb 44B1 for flow cytometric analysis. mAb 31C6 (Fig. 4) and the three other inhibitory mAbs, 110, 44B1 and 72 (data not shown), showed the same retention of mAb–PrPC complexes as observed with Neuro2a cells.



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Fig. 4. Retention of mAb–PrPC complexes on the cell surface. Neuro2a (left panel) or I3/I5-9 cells cured of PrPSc by mAb treatment (right panel) were cultured for 1 h in the presence of 10 µg negative control mAb P1-284 (a) or mAb 31C6 (b, c) ml–1. Cells were harvested immediately and stained with Alexa-488-conjugated secondary antibody (a, b). Alternatively, after the removal of mAb, the cells were cultured for an additional 4 h in the absence of mAb and then harvested and stained with the secondary antibody (c).

 
To confirm further the retention of mAb–PrPC complexes on the cell surface, Neuro2a and I3/I5-9 cells were cultured for 1 h with mAbs 110, 31C6, 44B1 and 72, and, in some cases, the cells were cultured for an additional 4 h with mAb-free medium. The cells were then fixed with ice-cold methanol and mAb–PrPC complexes were detected using secondary antibody (Fig. 5). All mAbs bound to the cell surface (Fig. 5a–e) and membrane staining could be detected, even after 4 h incubation in the absence of mAbs (Fig. 5f–j). To characterize further the retention of mAb–PrPC complexes on the cell surface, we examined the effect of DS500, which is reported to accelerate PrPC endocytosis (Shyng et al., 1995). Following treatment with DS500, the mAb–PrPC complexes on the cell surface were internalized and detected as intracellular granules (Fig. 5k–o). These results demonstrated that the mAbs bound to the cell-surface PrPC remained there, regardless of their epitope specificity.



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Fig. 5. Internalization of mAb–PrPC complexes by treatment with DS500. Neuro2a cells (a, f and k) and I3/I5-9 cells (b–e, g–j, l–o) were cultured for 1 h with mAb 110 (b, g and l), 31C6 (a, f and k for Neuro2a cells; c, h and m for I3/I5-9 cells), 44B1 (d, i and n) or 72 (e, j and o). After removal of the mAb, cells were washed with ice-cold PBS and fixed with ice-cold methanol (a–e). Alternatively, after removal of mAb, cells were cultured with mAb-free medium for 4 h and fixed with ice-cold methanol (f–j). For DS500 treatment (k–o), after removal of mAb, cells were cultured for 3 h in mAb-free medium and then treated for 1 h with 25 µg DS500 ml–1, after which they were fixed with ice-cold methanol. The fixed cells were directly stained with Alexa-488-conjugated secondary antibody to detect bound anti-PrP mAb.

 
Effect of other compounds on PrPC expression
Our results indicated a possible link between cell-surface retention of PrPC by anti-PrP antibodies and the inhibition of PrPSc formation in cells, and suggested that the mAb treatment altered the total amount of PrPC at least for mAbs 110 and 44B1. In order to examine whether compounds that inhibit PrPSc accumulation in prion-infected cells affect PrPC level in the cells, we tested DS500, E-64d, quinacrine, chlorpromazine and polyethyleneimine. We confirmed that these compounds inhibited PrPSc accumulation in I3/I5-9 cells (data not shown). Using the concentrations at which these compounds caused >90 % inhibition, we examined their effects on cellular levels of PrPC following a 3-day treatment (Fig. 6a). Immunoblot analysis revealed that only DS500 reduced the PrPC level (to ~30 % that of untreated cells) among the compounds tested. Flow cytometric analysis with mAb 110 (Fig. 6b) confirmed that DS500 reduced the level of cell-surface PrPC.



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Fig. 6. Influence of chemical treatments on the expression of PrPC. (a) Total amount of PrPC. Neuro2a cells were treated for 12 h with various chemical compounds as indicated above the panel. Final concentrations were 3 µg chlorpromazine (CP) ml–1, 25 µg DS500 (DS) ml–1, 50 µM E-64d (E64d), 3 µg polyethyleneimine (PEI) ml–1 and 2 µM quinacrine (QC). Total PrPC was detected in cell lysates by immunoblot analysis using mAb 31C6 (upper panel). The same blot was probed with anti-sarcomeric actin mAb to normalize for loading (lower panel). The intensity of the bands was quantified using an LAS-1000 lumino image analyser, and the relative amount of PrPC compared with untreated control (NT) was calculated for each experiment. The data below the panel are means from three independent experiments. (b) Representative flow cytometric analysis of the cell-surface expression of PrPC. Neuro2a cells were treated with compounds as described in (a), harvested, stained with mAb 110 followed by Alexa-488-conjugated secondary antibody and analysed by flow cytometry. The mean fluorescence intensity of the untreated control (NT) was assigned a value of 1 and the relative fluorescence intensities were calculated from the mean fluorescence intensity from each histogram. Quinarine was excluded from this experiment because of its autofluorescence. mAb P1-284 was used as a negative control for flow cytometric analysis.

 
Since sulfated glycosaminoglycans like DS500 may bind to the N-terminal region of PrPC (Pan et al., 2002), the reduction in fluorescence intensity may be due to blocking of mAb 110 binding. For this reason, we used mAbs 31C6 and 44B1 to detect PrPC instead of mAb 110. Table 1 shows the mean relative amount of PrPC on the cell surface calculated from at least three independent experiments. Regardless of the mAb used for detection, DS500 reduced the PrPC level to ~50 % of the untreated control. No significant change in cell-surface expression of PrPC was observed with the other compounds tested.


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Table 1. Effects of chemical treatment on cell-surface expression of PrPC

Data represent means±SD (minimum of n=3) of relative fluorescence intensity compared with control (NT).

 

   DISCUSSION
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Anti-PrP antibodies that react with the C-terminal portion of PrP inhibit PrPSc formation in cultured cells (Enari et al., 2001; Peretz et al., 2001). One explanation for the inhibitory effect of these antibodies is that the binding of mAb to the corresponding epitope on PrPC directly inhibits PrPC–PrPSc interaction by occupying their binding domains. Fab D18, the most effective mAb reported by Peretz et al. (2001), reacts with the region spanning aa 132–156 in mouse PrP. In this study, we examined three mAbs recognizing epitopes within this region, but only mAb 31C6, which recognizes aa 143–149, displayed inhibitory activity. The remaining mAbs, 118 and 149, which bind adjacent epitopes aa 137–143 and aa 147–151, respectively, did not inhibit PrPSc formation in the cells. The main difference among these three mAbs was their ability to bind mature PrPC; only mAb 31C6 bound PrPC on the cell surface. Although it is well known that the N-terminal portion of PrP, including the octapeptide repeat, is not essential for prion propagation and/or PrPSc formation (Flechsig et al., 2000; Rogers et al., 1993), mAb 110, which recognizes the sequence in the octapeptide repeat, also antagonized PrPSc formation. This implied that there are mechanisms of inhibition other than blocking of the specific epitopes. Indeed, four of eight anti-PrP mAbs recognizing different epitopes inhibited PrPSc formation, suggesting that a common feature of the inhibitory mAbs is their ability to bind PrPC on the cell surface. Taken together, our results suggest that inhibition of PrPSc formation by mAbs depends on their binding to mature PrPC on the cell surface rather than their binding to specific epitopes. On the other hand, transient interaction between the flexible N-terminal region and the second {alpha}-helix in the C-terminal globular domain has been postulated (Zahn et al., 2000), and antibody binding to the N terminus of PrP prevents binding of C terminus-specific mAb (Li et al., 2000). Hence, it cannot be excluded that binding of mAb 110 to the octapeptide repeat might sterically influence a particular domain involved in binding to PrPSc.

Although the cell-surface binding of mAb 110 was lower than that of the other mAbs (Fig. 1b, left panel), it inhibited PrPSc formation as efficiently. This may be explained by the presence of an 18 kDa N-terminally truncated PrPC. This truncated PrPC fragment is produced by cleavage of PrPC around residue 112 during the recycling process (Chen et al., 1995) so that it is not recognized by mAb 110. Recently, Mishra et al. (2002) reported that the N-terminally truncated form comprised as much as 40–50 % of PrPC on the cell surface. This could account for the lower signals obtained using mAb 110. Because N-terminally truncated PrPC is unlikely to act as a substrate for prion propagation and/or PrPSc formation (Lawson et al., 2001; Weissmann, 1999), the binding of mAb 110 to PrPC possessing the N-terminal portion is apparently sufficient for the inhibition of PrPSc formation.<~?tpb=7pt>

In this work, we have demonstrated both quantitatively and qualitatively that mAbs that bind to cell-surface PrPC remain attached to the membrane, even after withdrawal of the mAbs from the culture medium. This suggests that the mAb–PrPC complex on the cell surface is not preferentially internalized into the cell. Mature PrPC expressed on the cell surface is thought to be internalized via either clathrin-coated or -uncoated vesicles from which it enters the degradation pathway (Peters et al., 2003; Shyng et al., 1994; Sunyach et al., 2003). Because PrPSc formation is believed to take place in the subcellular compartments that include cell membrane during the degradation pathway (Borchelt et al., 1992; Caughey & Raymond, 1991), it is possible that mAb treatment could interfere with the regular PrPC metabolism simply by retaining it on the cell surface. We suspected that the cell-surface retention of PrPC would result in an increase in total PrPC. Actually, two mAbs, 110 and 44B1, obviously increased the total amount of PrPC, while two other mAbs 31C6 and 72 did not influence the total amount of PrPC. It is conceivable that binding of mAbs to specific epitopes of cell-surface PrPC might result in downregulation of PrPC synthesis; however, further experiments are required to resolve this.

It was recently reported that polyclonal antibodies against dimeric recombinant PrP inhibited PrPSc formation in the cell, while the corresponding Fab fragments had little effect on PrPSc formation (Gilch et al., 2003). This suggests that antibody-mediated cross-linking of PrPC on the cell surface is important for inhibition of PrPSc formation. Whether cross-linking of PrPC by IgG is required for the retention of the mAb–PrPC complex under our experimental conditions remains to be determined. Treatment of cells persistently infected with prions using antibodies against the laminin receptor precursor/laminin receptor (LRP/LR) reduced PrPSc accumulation (Leucht et al., 2003). Because binding of LRP/LR to PrPC could be involved in PrP metabolism (Gauczynski et al., 2001), it is conceivable that antibodies interfere with the interaction between PrPC and a molecule(s) that participates in PrPC internalization.

Many reagents, including small molecules, recombinant PrP and anti-PrP antibodies, have been identified as potential inhibitors of prion propagation. It is important to elucidate their mechanisms of action, not only for the establishment of therapeutics but also for an understanding of prion replication. In the present study, we have demonstrated that blocking of the internalization of PrPC with anti-PrP mAbs prevents PrPSc accumulation. Although anti-PrP mAbs recognizing specific epitopes have recently been reported to induce neuronal death in the hippocampus and cerebellum (Solforosi et al., 2004), we have not found an apparent adverse effect on the cell growth and clinical manifestation by intraventricular inoculation of the anti-PrP mAbs used in this study (data not shown). Further analyses using prion-infected animals are necessary for evaluation of anti-PrP antibodies as therapeutics for treating prion diseases.

After the submission of this paper, a paper was published by Perrier et al. (2004) in which it was described that recognition by mAb SAF34 of the octapeptide repeat region on the N-terminal part of human PrP inhibited PrPSc formation in prion-infected neuroblastoma cells.


   ACKNOWLEDGEMENTS
 
This work was supported by a grant from The 21st Century COE Program (A-1) and a Grant-in-Aid for Science Research (A) (grant 15208029) and (B) (grant 12460130) from the Ministry of Education, Culture, Sports, Science and Technology, Japan. This work was also supported by a grant from the Ministry of Health, Labour and Welfare of Japan.


   REFERENCES
Top
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
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Received 16 March 2004; accepted 26 July 2004.