Evidence of Presynaptic Location and Function of the Prion Protein

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The Journal of Neuroscience, October 15, 1999, 19(20):8866-8875

Evidence of Presynaptic Location and Function of the Prion Protein
Jochen Herms¹, Tobias Tings¹, Stefan Gall¹, Axel Madlung¹, Armin Giese¹, Heike Siebert¹, Peter Schürmann¹, Otto Windl¹, Nils Brose², and Hans Kretzschmar¹
¹ Department of Neuropathology, Georg-August Universität Göttingen, 37075 Göttingen, Germany; ² Max-Planck-Institut für Experimentelle Medizin, 37073 Göttingen, Germany

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The prion protein (PrP^C) is a copper-binding protein of unknown function that plays an important role in the etiology of transmissiblespongiform encephalopathies. Using morphological techniques andsynaptosomal fractionation methods, we show that PrP^C is predominantly localized to synaptic membranes. Atomic absorptionspectroscopy was used to identify PrP^C-related changes in the synaptosomal copper concentration in transgenicmouse lines. The synaptic transmission in the presence of H₂O₂,which is known to be decomposed to highly reactive hydroxyl radicalsin the presence of iron or copper and to alter synaptic activity,was studied in these animals. The response of synaptic activityto H₂O₂ was found to correlate with the amount of PrP^C expression in the presynaptic neuron in cerebellar slice preparationsfrom wild-type, Prnp^0/0, and PrP gene-reconstituted transgenic mice. Thus, our data givesstrong evidence for the predominantly synaptic location of PrP^C, its involvement in the regulation of the presynaptic copperconcentration, and synaptic activity in definedconditions.

Key words: prion protein; synaptosomes; synaptic transmission; hydrogen peroxide; copper; cerebellum

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The prion protein (PrP) is a sialoglycoprotein localized at the cell surface (Stahl et al., 1987). It is mainly expressedin the CNS, particularly in neurons (Kretzschmar et al., 1986;Moser et al., 1995) and to a lesser extent in extraneural tissues(Bendheim et al., 1992; Manson et al., 1992b). In prion diseases,a post-translational modification of the cellular prion protein(PrP^C) leads to the accumulation of an abnormal, conformationally alteredisoform, PrP^Sc (Prusiner et al., 1996), particularly in the neuropil (Kitamotoet al., 1992).

The localization of PrP^C within neurons, however, is not clear. The majority of immunohistochemical studies describe a somaticexpression of PrP^C in neurons with no or only a minor signal in the neuropil (DeArmondet al., 1987; Piccardo et al., 1990; Safar et al., 1990; Bendheimet al., 1992). Data obtained using the histoblot technique (Tarabouloset al., 1992) and electron microscopy (Fournier et al., 1995;Salès et al., 1998), however, indicate a synaptic localizationof PrP^C. Moreover, colocalization of PrP^C with the presynaptic vesicle protein synaptophysin was observed,and it has been speculated that PrP^C may be a constituent of the synaptic vesicle membrane or a productstored within vesicles (Fournier et al., 1995). However, the immunoelectronmicroscopic procedures used in these studies resulted in a destructionof cellular membranes leading to a loss of exact morphologicalPrP^Clocation.

Attempts to identify the role of PrP^C in synaptic transmission have yielded controversial results (Collinge et al., 1994; Hermset al., 1995; Manson et al., 1995; Whittington et al., 1995; Lledoet al., 1996). Altered GABA_A receptor-mediated synaptic transmissionin the hippocampus of Prnp^0/0 mice was observed, and postsynaptic mechanisms were implicated(Collinge et al., 1994). Outside-out membrane patches of cerebellarPurkinje cells, however, did not reveal any alteration of theGABA_A receptor in Prnp^0/0 mice (Herms et al., 1995). Also, the described alteration inthe rise time of IPSCs in hippocampal CA1 neurons (Collinge etal., 1994) could not be reproduced in either cerebellar Purkinjecells (Herms et al., 1995) or hippocampal CA1 neurons (Lledo etal., 1996).

In this study, we used synaptosomal fractionation methods to determine the subcellular neuronal localization of PrP^C. These analyses were complemented by a more detailed morphologicalinvestigation of PrP^C expression using immunohistochemical techniques. Our resultssupport the notion that PrP^C is predominantly expressed at the presynaptic membrane. BecausePrP^C is known to bind copper, we used atomic absorption spectroscopyto show a reduction in the copper concentration in synaptosomalpreparations of Prnp^0/0mice.

For a functional analysis of PrP^C and the copper concentration at the presynapse, we performed patch-clamp measurements oncerebellar slice preparations of wild-type, Prnp^0/0, and PrP-reconstituted transgenic mice. For these experiments,we used hydrogen peroxide, which is known to alter synaptic vesiclerelease by reacting with metal ions, such as iron and copper atthe presynapse (Pellmar et al., 1994), by increasing the presynapticcalcium concentration. Using transgenic lines that express PrP^C in anatomically defined neurons, we observed that the effectof H₂O₂ on the frequency of spontaneous IPSCs (sIPSCs) in cerebellarPurkinje cells correlates with the amount of PrP^C expressed in the presynapticneuron.

Thus, our data show that PrP^C is localized to the synaptic membrane and that PrP^C is involved in regulating the presynaptic copper concentrationand synaptic transmission under biochemically definedconditions.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experimental animals. The animals used for these experiments were Prnp^0/0 mice (Büeler et al., 1992) and wild-type C57Bl/6J×129/sv(ev)hybrids. Also included in the analysis were mice overexpressingthe mouse Prnp-b allele (tg35) and the mouse Prnp-a allele (tg20)on a Prnp^0/0 background, as described previously (Fischer et al., 1996).

Subcellular fractionation. Synaptic plasma membranes (SPMs), synaptic vesicle (SV) fractions, and cytosolic synaptosomal (CS)fractions were prepared following standard protocols (Huttneret al., 1983; Brose et al., 1989). All procedures were performedat 4°C. Twenty brains of adult wild-type, Prnp^0/0, and tg35 mice were collected in 80 ml of ice-cold 0.32 M sucroseand homogenized using a glass-Teflon homogenizer. The resultinghomogenate was centrifuged at 800 × g for 10 min. The supernatantwas pelleted again at 9200 × g for 15 min. The resulting crudesynaptosomal pellet was washed by resuspension and recentrifugation(9200 × g for 15 min), resuspended in 15 ml of 0.32 M sucrose,and homogenized in 9 vol of H₂O containing 0.2 mM PMSF, 0.5 µg/mlleupeptin, and 1 µM pepstatin. The suspension was stirred at 4°Cfor 15 min. Centrifugation at 25,000 × g for 20 min produced apellet with lysed synaptosomal membranes. After ultracentrifugationof the supernatant at 230,000 × g for 2 hr, the supernatant containedthe CS fraction, and the pellet contained the crude SV fraction.The lysed synaptosomal membrane fraction was resuspended in 5ml of H₂O and loaded on a sucrose density gradient containing15 ml of 1.2 M sucrose, 15 ml of 0.8 M sucrose, and 5 ml of 0.3M sucrose. After centrifugation at 113,000 × g for 150 min ina Beckman Instruments (Fullerton, CA) SW 28 rotor, the SPM fractionband between 0.8 and 1.2 M sucrose wascollected.

Postsynaptic densities. Triton X-100 was used to separate postsynaptic densities (PSDs) from other synaptic elements basedon insolubility in the detergent (Carlin et al., 1980). The preparedcrude synaptosomal fraction was resuspended in buffer B (0.32M sucrose and 1 mM NaHCO₃) and loaded onto a sucrose density gradientcontaining 15 ml each of 1.4 and 1.0 M sucrose. After centrifugationat 82,500 × g for 60 min in a Beckman SW 28 rotor, the band between1.4 and 1.0 sucrose was collected and diluted in buffer B to afinal concentration of 4 mg/ml. After adding an equal volume of1% (v/v) Triton X-100, the suspension was stirred for 15 min at4°C and centrifuged at 32,800 × g for 10 min. The resulting pelletwas resuspended in buffer B and loaded on another sucrose densitygradient containing 4 ml of 2.0 M sucrose, 3 ml of 1.5 M sucroseand 3 ml of 1.0 M sucrose. After centrifugation at 201,800 × gfor 120 min in the Beckman SW 40 rotor, the PSD fraction bandbetween 1.5 and 2.0 M sucrose was collected, diluted in bufferB to a volume of 9 ml, mixed with an equal volume of 1% TritonX-100 in 150 mM KCl, loaded onto a further sucrose density gradientcontaining 1.5 ml each of 2.1 and 1.5 M sucrose, and spun at 113,000× g for 10 min using the Beckmann SW 40 rotor. This procedurewas repeated once. The PSD band was diluted in HEPES-KOH and pelletedat 113,500 × g for 10 min. The resulting pellet containing PSDswas collected in HEPES-KOHbuffer.

Preparation of synaptosomes. Synaptosomes were prepared by a modification of the procedure of Nicholls (McMahon et al., 1992).Five brains, excluding brainstem of female, 2-month-old wild-type,Prnp^0/0, and tg20 mice were collected in 30 ml of ice-cold 0.32 M sucroseand homogenized using a glass-Teflon homogenizer. The resultinghomogenate was centrifuged at 3440 × g for 2 min. The supernatantwas pelleted again at 16,700 × g for 12 min. The resulting crudesynaptosomal pellet was resuspended in 4 ml of 0.32 M sucroseand put on a three-step Ficoll (Amersham Pharmacia Biotech, München,Germany) gradient (6, 9, and 13%). After centrifugation at 64,000× g for 35 min, the interfaces were collected and pooled. Theintegrity of the synaptosomes was confirmed by electronmicroscopy.

Atomic absorption spectroscopy. Synaptosomes were dried at 150°C overnight and ashed at low temperature for 24 hr using plasmaprocessor TePLa 100-e (Technics Plasma). The residue was absorbedin nitric acid. Cu measurements were performed using a Zeeman3030 (Perkin-Elmer, Emeryville, CA) flameless atomic absorptionspectrophotometer at a wavelength of 325.2 nm after rapid atomizationat 2000°C in a graphite-tube cuvette HGA-70 (Perkin-Elmer).

Antibodies. Murine PrP^C was detected using either a rabbit antiserum (Ra5) raised against a synthetic peptide correspondingto amino acid residues 107-122 (Groschup et al., 1994) or themonoclonal antibody 3B5 raised by DNA-mediated immunization ofPrnp^0/0 mice and mapped to amino acids 54-69 of human PrP (Krasemannet al., 1996). Polyclonal antibodies to synaptotagmin I (Perinet al., 1990) were a gift from T. C. Südhof (Dallas, TX). Monoclonalantibodies to NMDA-R1 were raised against a fusion protein ofNMDA-R1 with glutathione S-transferase (Brose et al., 1994).

SDS-PAGE and Western blot analysis. Protein samples were quantified by standard procedures (BCA Protein Assay; Sigma, Deisenhofen,Germany) with bovine serum albumin as a standard. SDS-PAGE wasperformed using either 10 or 15% gels. Proteins were transferredto a nitrocellulose membrane (Schleicher & Schuell, Göttingen,Germany) using a semi-dry electrotransfer system (Phase, Lübeck,Germany). The blots were blocked with 0.2% I-Block (Tropix, Bedford,MA) in PBS-0.1% Tween 20 for 30 min and were then incubated withprimary antibodies for 1 hr at room temperature, followed by anincubation with alkaline phosphatase (AP)-conjugated goat anti-rabbitor anti-mouse antibodies from Dako (Hamburg, Germany) (1:500)for 1 hr at room temperature. After the incubation steps, themembranes were washed with PBS-0.1% Tween 20. Immunopositive signalswere detected using the chemiluminescent substrate CDP-StarTM(Tropix) following the manufacturer's instructions. The lightsignals were monitored, documented, and quantified using a CCD-videosystem and the accompanying software (Raytest, Straubenhardt,Germany). Blots were developed using nitroblue-tetrazolium-chloride(NBT) and 5-brom-4-chlor-indolyl-phosphate (BCIP) (BoehringerMannheim, Mannheim,Germany).

Immunohistochemistry of cryostat sections. Animals were killed by an overdose of 7% chloral hydrate, and their eyes were immediatelyremoved from the sockets. The eyes were mounted in Tissue Tek(OCT compound; Miles Inc., Elkhart, IN) and rapidly frozen inprecooled isopentane; the same procedure was performed for thebrain after removal from the skull. The samples were kept at $-$ 80°Cuntil sectioning. Sections of 8 µm thickness were made at $-$ 20°C,air-dried, fixed in ethanol for 10 min, and kept at $-$ 20°C. Frozensections were thawed, rinsed in 0.1 PBS, pH 7.4, and blocked with2% bovine serum albumin. The sections were incubated with an undilutedmedium supernatant containing the monoclonal antibody 3B5. Afterrinsing, the slides were incubated with a fluorescent goat anti-mouseantibody (Oregon Green 488; 1:200; Molecular Probes, Eugene, OR).For synaptophysin immunohistochemistry, sections were treatedas described above and incubated overnight with a monoclonal antibodyagainst synaptophysin (1:10; Boehringer Mannheim). A tetramethylrhodamineisothiocyanate-coupled goat anti-mouse IgG was used as a secondaryantibody (1:200; Dianova, Hamburg, Germany). Sections were examinedusing the Leica (Heidelberg, Germany) TCS NT laser scanning systemmounted on an Olympus Opticals (Tokyo, Japan) BX50 WImicroscope.

Histoblots. Histoblots for the detection of PrP^C were performed using a modification of the method described previously (Tarabouloset al., 1992). Sections of frozen brain tissue were cut at 10µm and immediately transferred onto nitrocellulose membranes thathad been wetted in lysis buffer (0.5% NP-40, 0.5% sodium desoxycholate,100 mM NaCl, 10 mM EDTA, and 10 mM Tris-HCl, pH 7.8). The membraneswere air-dried thoroughly and rehydrated for 1 hr in TBST-buffer(100 mM NaCl, 0.05% Tween 20, and 10 mM Tris-HCl, pH 7.8). Blotswere rinsed three times in TBST, then blocked with 5% nonfat drymilk, rinsed in TBST again, and incubated for 12 hr at 4°C withantiserum Ra5 in TBST and 1% nonfat milk. Rabbit antiserum wasused at a dilution of 1:500. Secondary goat anti-rabbit AP-conjugatedantibody (Dako) was used at a dilution of 1:1000 in TBST and 1%nonfat milk. Blots were developed using NBT and BCIP (BoehringerMannheim).

Whole-cell voltage-clamp recordings of cerebellar Purkinje cells. Patch-clamp experiments were performed on Purkinje cellsin thin slices of the cerebellum following standard procedures(Hamill et al., 1981; Edwards et al., 1989). Sagittal slices ofcerebellum (150 µm) were prepared from 9- to 13-d-old mice asdescribed previously (Edwards et al., 1989; Herms et al., 1995)and maintained at 37°C in a continuously bubbled (95% O₂ and 5%CO₂) solution (125 mM NaCl, 2.5 mM KCl, 1.25 mM NaH₂PO₄, 26 mMNaHCO₃, 2 mM CaCl₂, 1 mM MgCl₂, and 25 mM glucose). After 60 minrecovery, the slices were placed in the recording chamber andsuperfused with the above solution at room temperature. A Purkinjecell was selected using an upright microscope with a 63× water-immersionlens (Zeiss, Göttingen, Germany). Electrodes were pulled fromborosilicate glass capillaries and filled with a solution containing(in mM 140 CsCl, 10 HEPES, 10 EGTA, 1 CaCl₂, 2 MgCl₂, 4 Na₂-ATP,and 0.4 Na₃-GTP (adjusted to pH 7.3 with CsOH). Single-electrodevoltage-clamp recordings (Edwards et al., 1989) were performedwith a patch-clamp amplifier (EPC-9; Heka Elektronik, Lambrecht,Germany) using optimal series resistance compensation as recommended(Llano et al., 1991). The whole-cell capacitance and series resistance(R_s) adjustment of the amplifier were used to compensate the initialportion of the capacitance transient elicited by 10 mV hyperpolarizingpulses and to estimate the value of the series resistance (Llanoet al., 1991). The series resistance of Purkinje cells beforecompensation was typically 3-10 M $Omega$ . No significant differenceswere observed here between the different transgenes studied andwild-type Purkinje cells. Series-resistance compensation was setat between 60 and 70%. R_s was monitored throughout the experimentsby hyperpolarizing pulses applied every 30 sec. The experimentwas discontinued if the series resistance increased above 15 M $Omega$ or >20% of the initial value. Our results are derived from a dataset of 96 Purkinjecells.

H₂O₂ was diluted daily from a 30% stock solution and applied by bath perfusion. Given the perfusion rate of 1.0-1.5 ml/minand the volume of 1.1 ml of the chamber, exchange of the externalsolution was achieved within a very short time. The bath solutionscontained 10 µM of the antagonist of ionotropic glutamate receptors6-cyano-7-nitroquinoxaline-2,3-dione, as well as in some experiments0.5 µM tetrodotoxin (TTX) purchased from Biotrend (Köln, Germany).All other chemicals used were purchased fromSigma.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Detection of PrP^C in histoblots

Histoblots of brain sections from wild-type and PrP^C-overexpressing mice (tg35) were immunostained to analyze the pattern ofPrP^C expression. Only a very weak, non-definitive signal was detectedin wild-type mice (Fig. 1A). No signal was seen in Prnp^0/0 mice, which served as negative controls (Fig. 1B). However, strongstaining was seen on brain sections from tg35 mice overexpressingPrP^C (Fig. 1C). In these mice, strong staining was found in regionsof high synaptic density, i.e., in hippocampal stratum oriens,stratum radiatum, stratum lacunosum moleculare (Fig. 1D), andin the molecular layer of the cerebellum (Fig. 1F). The signalwas absent in regions primarily consisting of nerve cell somata,i.e., in the granular layer of the hippocampal dentate gyrus andthe stratum pyramidale of the hippocampal CA1 region (Fig. 1E,hematoxilin-eosin stain of a parallel section). Intermediate-to-faintstaining was observed in the cerebral cortex and other gray matterregions without localization to specific cortical regions or layers.

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Figure 1. PrP^C is preferentially localized to areas of high synaptic density. Histoblots of wild-type (A), Prnp^0/0 (B), and PrP^C-overexpressing reconstituted Prnp^0/0 (tg35) (C) mice. The blots were probed with anti-PrP antiserum Ra5. No PrP^C was detected in Prnp^0/0 mice (B) or in wild-type mouse brains (A). D and F show enlargements from boxes in C. E and G show consecutive hematoxilin and eosin stains. D, E, PrP^C is strongly expressed in areas of high synaptic density of the hippocampal stratum orients (1), stratum radiatum (3), stratum lacunosum moleculare (4), and the molecular layer (5). No signal was detected in the hippocampal pyramidal cell layer (2) or the granular layer of the dentate gyrus (6). F, G, High PrP^C expression in the cerebellar molecular layer (7). Scale bars: A, 1 mm; B, C, 2.5 mm; D-G, 250 µm.

Localization of PrP^C in mouse cerebellum and retina of transgenic animals

Further immunohistochemical examination using confocal laser microscopy revealed highest expression of PrP^C in the cerebellar molecular layer in both tg20 mice and tg35mice (Fig. 2A,B). Here, PrP^C was found to be coexpressed with synaptophysin (data not shown).In tg35 mice, the Purkinje cell bodies also showed immunoreactivity,whereas in tg20 mice, we observed no signal in the Purkinje celllayer (Fig. 2B), consistent with the finding that tg20 Purkinjecells do not express PrP^C (Fischer et al., 1996).

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Figure 2. Laser scanning confocal images of PrP^C in the cerebellar cortex and retina of wild-type and PrP^C-overexpressing Prnp^0/0-reconstituted mice. A, B, Cerebellar cortex of tg35 and tg20 animals analyzed using PrP antibody 3B5. In tg35 (A), PrP^C was detected over the granule cell layer (gcl), the Purkinje cell bodies (pcl), and the molecular layer (ml). In tg20 (B), a strong PrP^C expression was observed over the molecular layer and granule cell layer but not in the Purkinje cell layer. C-F, Retina of wild-type (C) and PrP^C-overexpressing tg20 (D-F) mice. Using PrP antibody 3B5, no signal was detected in wild-type mice (C), whereas the tg20 retina (D) showed a strong PrP^C expression in the inner plexiform layer (ipl), as well as the outer plexiform layer (opl). In tg20 mice, synaptophysin (E) was found to be coexpressed with PrP^C in the outer and inner plexiform layers (F). PrP^C expression is low in the outer (onl) and inner nuclear layers (inl). Scale bars: A-F, 150 µm.

Both transgenic lines showed strong immunoreactivity in the molecular layer, which is primarily composed of granule cell axons(parallel fibers) and Purkinje cell dendrites. Because Purkinjecells of tg20 mice do not express PrP^C, the strong PrP^C immunoreactivity in the molecular layer of these animals doesnot originate from the Purkinje cell dendrites, but mostly fromgranule cellaxons.

No signal was detected in wild-type retina (Fig. 2C). Within the retina of a transgenic line overexpressing PrP^C (tg20), immunohistochemistry revealed strong staining in theinner and outer plexiform layers (Fig. 2D), which are regionsof high synaptic density, as shown by synaptophysin immunohistochemistry(Fig. 2E). There was only low immunoreactivity in the internalor external granule cell layers. Very low PrP^C immunoreactivity was observed in the inner segments of the photoreceptorcells. No PrP^C immunopositivity was detected in the outer segments. Figure 2Fclearly shows that PrP^C is colocated with the synaptic proteinsynaptophysin.

Preferential localization of PrP^C in the synaptic membrane fraction

Biochemical preparation of subcellular fractions of wild-type mice and PrP^C-overexpressing mice was used to more clearly define the localizationof PrP^C in wild-type neurons and to compare these with PrP^C-overexpressing neurons. Whole-brain homogenates, crude SV fractions,CS fractions, and SPM fractions from adult mice were isolated.The synaptic plasma membrane fraction from Prnp^0/0 mice served as control. Using the antibody 3B5 (Fig. 3A,C) andthe antiserum Ra5 (Fig. 3B), we observed a strong PrP^C signal in the SPM fraction in wild-type mice (Fig. 3A,B) andin tg35 (Fig. 3C). The two main glycosylated forms (33-35 and30 kDa) and one unglycosylated form (27 kDa) of PrP^C were clearly distinguishable. A small band was seen in the SPMfraction of Prnp^0/0 mice (Fig. 3A), which was unspecific because it was not detectablein the blot probed with a different PrP antibody (Fig. 3B). PrP^C was also detected in the crude synaptic vesicle fraction in bothwild-type and PrP^C-overexpressing mice (Fig. 3A-C, SV). In contrast to the synapticvesicle protein synaptotagmin (Fig. 3D), there was a strongerband of PrP^C in the SPM fraction than in the crude synaptic vesicle fraction(Fig. 3A-C). Neither synaptotagmin nor PrP^C were detected in the CS fraction (Fig. 3A-D). A comparison ofthe PrP^C signal of the brain homogenate with the PrP^C signal from the SPM fraction showed an enrichment factor of 3to 4 in both wild-type mice and PrP^C-overexpressing mice. As shown in a Western blot with an antibodydirected against NMDA receptor subunit 1, the synaptic vesiclefraction is not pure (Fig. 3E). Although these results show thatthe major amount of PrP^C is localized to the synaptic plasma membrane, it remains unclearwhat proportion of PrP^C is in the synaptic vesicle fraction.

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Figure 3. Enrichment of PrP^C in the synaptic plasma membrane fraction but not in the postsynaptic density fraction isolated from mouse brains. Equal amounts (100 µg/lane) of subcellular fractions from wild-type mouse brain and prion protein-deficient mouse brain (Prnp^0/0) were analyzed by immunoblotting with anti-PrP antibody 3B5 (A) and antiserum Ra5 (B). For comparison, subcellular fractions of PrP^C-overexpressing tg 35 mice (30 µg/lane) were also examined using antibody Ra5 (C). The immunostaining for synaptotagmin (D) and NMDA receptor subunit NMDA-R1 (E) was used as a control for synaptic vesicle proteins and postsynaptic membrane proteins, respectively. Subcellular fractions are designated as follows: H, homogenate; SV, crude synaptic vesicle fraction; CS, cytosolic synaptosomal fraction; SPM, synaptic plasma membranes. F, In the PSD fraction, PrP^C is not detectable (Western blot analysis in homogenates and PSD with antibody 3B5; 30 µg of protein were loaded in each lane). G, Immunostaining for NMDA-R1 was used as a control for postsynaptic membrane proteins.

To address the subcellular localization of PrP^C in synapses more directly, we quantified the relative amounts of PrP^C on the cell surface and on transport-synaptic vesicles. For thatpurpose, we isolated Ficoll-purified synaptosomes and treatedthese with trypsin. This treatment should lead to complete degradationof the cell surface-plasma membrane pool of PrP^C but leave intracellular vesicular pools unaffected. We foundthat trypsin digestion of Ficoll-purified synaptosomes leads tocomplete degradation of all detectable synaptosomal PrP^C, indicating that very little or no PrP^C is present on synaptic vesicles. In contrast, the synaptic vesicleprotein synaptotagmin remained intact under these conditions (datanot shown). This finding further supports the notion that PrP^C is located predominantly on the synaptic plasma membrane ratherthan on the synaptic vesicle membrane, as proposed by Fournieret al. (1995).

For a clearer location of PrP^C at the presynaptic or postsynaptic membrane, we isolated PSDs. In contrast to the NMDA receptorsubunit 1 (Fig. 3G), a protein known to be present in this fraction,PrP^C was not detected in the postsynaptic density fraction of wild-typemice (Fig. 3F, using the Ra5 PrP antibody as in B).

Copper concentration in synaptosomes is related to PrP^C

A strong correlation of the prion protein expression and the copper content of crude membrane-enriched fractions from brainhomogenates has been described previously (Brown et al., 1997a).Whole-brain homogenates, however, do not show any significantdifference in the copper content between wild-type, Prnp^0/0, and PrP^C-overexpressing mice (Fig. 4A). However, differences were observedin synaptosomal preparations, fractions in which PrP^C is enriched (Fig. 4B). Here, the copper concentration was significantlylower in Prnp^0/0 (23 ± 6 ng of Cu/mg of protein) than in wild-type mouse preparations(39 ± 9 ng of Cu/mg of protein). In tg20 mice, which overexpressPrP^C on a Prnp^0/0 background, the copper concentration was found to be in the samerange as in wild-type animals (40 ± 13 ng of Cu/mg of protein).

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Figure 4. Copper concentration in synaptosomes correlates with PrP^C expression. The copper concentration in whole-brain homogenates (A) and synaptosomal fractions (B) of wild-type (WT), Prnp^0/0, and Prnp-reconstituted Prnp^0/0 mice (tg20) was studied by atomic absorption spectroscopy. The copper concentration was not significantly different in the whole-brain homogenates of the three lines tested. The synaptosomal preparations reveal a significantly reduced copper concentration in Prnp^0/0 mice compared with wild-type mice (Student's t test; p < 0.05). In PrP^C gene-reconstituted Prnp^0/0 mice (tg20), the synaptosomal copper concentration was similar to wild-type mice. Shown are the mean and SE for four to six independent preparations of five age- and sex-matched brains. Asterisks indicate that the observed differences were found to be statistically significant.

Effect of hydrogen peroxide on inhibitory synaptic transmission in wild-type, Prnp^0/0, and PrP^C-overexpressing mice

Biochemical investigation has shown a predominant location of PrP^C at the synaptic plasma membrane, and atomic absorption measurementshave revealed that synaptosomal copper concentration is relatedto PrP^C. Copper binding by PrP^C may therefore have functional consequences for synaptic transmission(Brown et al., 1997a). Here, we studied the effect of hydrogenperoxide, which is known to react with metal ions such as copperto form highly reactive oxygen species. These have been shownto modulate synaptic transmission predominantly on a presynapticlevel (Gilman et al., 1992; Palmeira et al., 1993; Pellmar etal., 1994; Pellmar, 1995).

Figure 5 illustrates the effect of 0.01% H₂O₂ on the inhibitory synaptic activity of a Purkinje cell in wild-type (A-G) andPrnp^0/0 (H-N) mice. A and H display a sample of a continuous recordingof sIPSCs in control saline 5 min before the application of H₂O₂,as indicated in Figure 5, C and J. Spontaneous IPSCs were recordedas inward currents because of the fact that the Nernst equilibriumpotential for Cl $-$ ions is close to 0 mV. B and I correspond tosamples of sIPSCs taken from the same cells 8 min after additionof 0.01% H₂O₂ to the external solution. The application led toa marked enhancement of synaptic activity in wild-type mice (B),whereas there was no comparable effect in Prnp^0/0 mice (I). The time course of the H₂O₂ effect on the sIPSC frequency,mean amplitude, and mean charge is shown in C-E for the wild-typePurkinje cells and in J-L for the Prnp^0/0 mice Purkinje cells. In wild-type mice, the enhancement of thesIPSC frequency after the application of H₂O₂ (0.01%) developsprogressively, reaching a peak value 15 min after the applicationhas been seeded (Fig. 5C). In Prnp^0/0 mice, the sIPSC increases only very transient during the H₂O₂application and decays during the following 10 min to values slightlylower than the frequency before the application (Fig. 5J).

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Figure 5. Hydrogen peroxide enhances inhibitory synaptic activity in wild-type (A-G), but not Prnp^0/0 (H-N) mouse Purkinje cells. Samples of the continuous recording of inhibitory synaptic currents before (A, H) and after (B, I) bath perfusion with 0.01% H₂O₂ at time points indicated in C and J. C and J show plots of the number of sIPSCs detected in 30 sec sample intervals as a function of time. The bar indicates the time of H₂O₂ application. D and K, as well as E and L, show the mean amplitudes and the mean charge of sIPSCs, calculated for 30 sec intervals, as a function of time. F and M show the amplitude histograms for the time periods (2.5 min) indicated in C and J. G and N show the cumulative amplitude distributions of the histograms shown in F and M. No shift in the amplitude distribution was observed in either the wild type (G) or Prnp^0/0 (N). The holding potential was $-$ 70 mV in this and all experiments shown in the following figures.

The plots of the mean IPSC amplitude (Fig. 5D) and the mean charge (E) showed no significant effect of H₂O₂ in wild-type miceon these parameters. In the Prnp^0/0 mouse Purkinje cell, the mean IPSC amplitude and charge decreasesslightly (K, L).

No significant changes were observed when comparing the amplitude histograms of the IPSCs (Fig. 5F,M) and the cumulative amplitudedistributions (G, N) recorded from equivalent time periods (2.5min), as indicated in Figure 5, C and J, before the applicationof H₂O₂ (Fa, Ma) and 10 min after the application of H₂O₂ (Fb,Mb).

Given that the major effect of H₂O₂ is an increase in the frequency of synaptic events, a presynaptic mechanism is very likelyinvolved. It was therefore of interest to determine whether thiseffect could be observed in the absence of Na⁺-dependent spikes in presynaptic neurons. In Purkinje cells studiedhere, the addition of TTX (0.5 µM) to the extracellular fluiddid not alter the increase of miniature IPSCs (mIPSCs) after treatmentwith H₂O₂ (255 ± 53% of the basal frequency; n = 4). Because H₂O₂increases the frequency of mIPSCs, this might result from an increasedmultiquantal release of transmitter caused by the discharge ofCa²⁺ spikes in the presynaptic inhibitory neurons. Experiments weretherefore performed under conditions designed to eliminate Ca²⁺ entry. However, a similar increase in mIPSC frequency (215 ±43%; n = 4) was observed in experiments in which Ca²⁺ was omitted from saline containing TTX and 200 µMEGTA.

No significant differences were observed in the resting membrane potentials and input resistances of Purkinje cells from Prnp^0/0 and wild-type mice, as described previously (Herms et al., 1995).H₂O₂ in the concentration used in this study was found to haveno effect on either parameter, similar to the observation madeby Pellmar et al.(1994) on hippocampal CA1 neurons. To elucidatewhether there is a general alteration in Prnp^0/0 mouse synapses, which does not allow an increase of the sIPSCfrequency because of a presynaptic stimulus, we studied the effectof the adenylyl cyclase activator forskolin. This is known toincrease sIPSC, as well as mIPSC, frequency (Llano and Gerschenfeld,1993). With the application of 10 µM forskolin, a similar increaseof sIPSC frequency in both wild-type mice and Prnp^0/0 mice was observed (170 ± 50% compared with 165 ± 48% in Prnp^0/0 mouse Purkinje cells; n =4).

To elucidate whether the differences observed between Prnp^0/0 and wild-type cells are caused by expression of PrP^C, we also examined transgenic mice, which overexpress PrP^C on a Prnp^0/0 background (tg35). Figure 6A-C shows a typical cell of a tg35mouse. In Figure 6A, the sIPSC frequency, calculated for 30 secintervals, is plotted as a function of time. As shown by the plot,the sIPSC frequency increased over sixfold when the response toH₂O₂ was maximal. No change in the mean sIPSC amplitude (Fig.6B) or a significant shift in the cumulative amplitude distribution(Fig. 6C) were observed.

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Figure 6. Hydrogen peroxide enhances inhibitory synaptic activity in two lines of Prnp-reconstituted Prnp^0/0 mice. PrP^C is overexpressed in all neurons in tg35 mice (A-C) and in all neurons except Purkinje cells in tg20 mice (D-F). A, D, Plots of the sIPSC frequency in 30 sec sample intervals against time in tg35 (A) and tg20 (D) mice. The bar indicates the time of H₂O₂ application. B, E, Plots of the mean sIPSCs amplitude, calculated for 30 sec intervals, as a function of time in tg35 (B) and tg20 (E) mice. C, G, Cumulative amplitude distributions for the time periods indicated in A and B. Whereas in tg35 (C) no significant shift can be observed, there is a shift to higher values in tg20 (F).

To elucidate whether the overexpression of PrP^C in either Purkinje cells or presynaptic neurons, i.e., stellate or basket cells,is the cause of the restored sIPSC frequency increase in PrP^C gene-reconstituted mice, we examined tg20 mice, which expressPrP^C in cerebellar interneurons but not Purkinje cells (Fischer etal., 1996) and are therefore ideally suited for the distinctionof presynaptic and postsynaptic effects when compared with Prnp^0/0 mice with no PrP^C expression at all and with tg35 and wild-type mice, which expressPrP^C in interneurons and Purkinje cells as well. Figure 6D-F showsthe response of a tg20 mouse Purkinje cell. The dramatic increasein the sIPSC frequency (Fig. 6D) after H₂O₂ application indicatesthat presynaptic PrP^C expression is important for the observed effect, whereas postsynapticPrP^C does not seem to be necessary. The plot of the mean sIPSC amplitude(E) showed a small increase after H₂O₂ application, as well asa shift of the cumulative amplitude distribution to higher values(F), which indicates that H₂O₂ also modulates the sIPSC amplitudein tg20mice.

Figure 7 illustrates cumulative data from 14 wild-type, 21 Prnp^0/0, 14 tg35, and 4 tg20 mouse Purkinje cells. In wild-type mice,the sIPSC frequency increased up to 250% of the level before H₂O₂application (A). In Prnp^0/0 mice, the mean sIPSC frequency increased only transiently, resumingits initial level 5 min after H₂O₂ application (A). In tg35 Purkinjecells, which overexpress PrP^C on a Prnp^0/0 background, an increase of the sIPSC frequency was observed (B).Moreover this increase was significantly stronger than in wild-typemice, indicating that the amount of PrP^C expressed is critical for the effect of H₂O₂ on synaptic transmission.A similar increase of the sIPSC frequency was observed in tg20mice (C). In wild-type and tg35 mice, the sIPSC amplitude wasnot altered by H₂O₂, whereas the mean values decreased in Prnp^0/0 mice. In tg20 mice, the mean sIPSC amplitude increased slightlyafter application of H₂O₂ (D).

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Figure 7. Pooled data of the effects of 0.01% H₂O₂ on the frequency and mean amplitude of Purkinje cell inhibitory synaptic currents in wild-type (), Prnp^0/0 ( $open circle$ ), tg35 (), and tg20 ( $triangle$ ) mice. Each point represents the mean ± SEM of frequency or amplitude of sIPSCs in 30 sec intervals normalized to the values before H₂O₂ application. Because of the tendency for amplitudes and frequencies of sIPSCs to decay slowly during the control period, only the last 3 min before the application were chosen for calculating the baseline (broken line at the 100% level). The threshold for detection of sIPSCs was set to $-$ 30 pA. A, Plots of the mean values of sIPSC frequency in wild-type (n = 14) and Prnp^0/0 (n = 21) mouse Purkinje cells, calculated for 30 sec intervals, as a function of time. The bar indicates the time during which H₂O₂ was applied. Significant differences between the two mouse strains are marked by asterisks. p < 0.01; t test. B, C, Plots of the mean values of the frequency of sIPSCs in tg35 (B; n = 15) and tg20 (C; n = 4) compared with wild-type and Prnp^0/0 mouse data. D, Plots of the mean sIPSC amplitudes normalized to values before H₂O₂ application in wild-type, Prnp^0/0, tg35, and tg20 mouse Purkinje cells. The amplitudes did not change in wild-type and tg35 cells after the application of H₂O₂. It increased slightly in tg20 mouse Purkinje cells and decreased significantly in Prnp^0/0 mouse cells.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Light microscopic studies on the cellular and subcellular location of PrP^C have yielded conflicting results. The majority of immunohistochemicalinvestigations have indicated a somatic staining pattern of PrP^C (DeArmond et al., 1987; Piccardo et al., 1990; Safar et al.,1990; Bendheim et al., 1992; Manson et al., 1992a). In the cerebellum,a strong staining of Purkinje cell bodies, but not of the neuropil,has been described (DeArmond et al., 1987; Manson et al., 1992a).In contrast, using the histoblot technique, Taraboulos et al.(1992) found a neuropil staining pattern in hamster brain. Thecerebellum was not examined in that study. More recently, an immunoelectronmicroscopic study (Fournier et al., 1995) demonstrated colocalizationof PrP^C with the presynaptic vesicle protein synaptophysin, which ledto the speculation that PrP^C might be a constituent of the synaptic vesicle membrane or aproduct stored within vesicles. Also, Salès et al. (1998) describedsynaptic staining in hamster brain using a highly sensitive free-floatingimmunohistochemical procedure. However, the electron microscopicdata did not give convincing evidence of a preferential expressionof PrP^C at the synaptic membrane because the tissue preservation in thatstudy was not of sufficient quality as a result of the preembeddingstaining technique that was used. On the functional level, previousphysiological data on Prnp^0/0 mice have also yielded contradictory results concerning the directinvolvement in the synaptic function of PrP^C (Collinge et al., 1994; Herms et al., 1995; Manson et al., 1995;Whittington et al., 1995; Lledo et al., 1996).

For a clarification of these questions, we performed biochemical, immunohistochemical, and electrophysiological experimentsusing various mouse lines. All investigations were performed onwild-type, PrP^C gene-ablated (Prnp^0/0), and PrP^C gene-reconstituted Prnp^0/0 (tg20 and tg35) mice. Because these transgenic lines differ intheir expression pattern of PrP^C, they were particularly suitable for our experiments. Tg35 miceexpress PrP^C in all neurons, whereas tg20 mice express PrP^C in all neurons except Purkinje cells (Fischer et al., 1996).These mice are therefore ideal for a functional analysis of presynapticand postsynaptic factors in the synaptic transmission of Purkinjecells depending on the PrP^Cexpression.

The histoblot data of PrP^C-overexpressing mice presented here clearly show that PrP^C immunostaining is most intense in regions of dense neuropil,such as the stratum radiatum and stratum oriens of the CA1 region,and is virtually absent from the granule cell layer of the dentategyrus and the pyramidal cell layer throughout the Ammon's horn.Immunohistochemistry of the retina shows the predominant locationof PrP^C in regions of high synaptic density, such as the inner and outerplexiform layers. The observed colocalization of PrP^C with the synaptic vesicle protein synaptophysin in the innerand outer plexiform layers is another strong indication of thesynaptic location of PrP^C.

Immunohistochemistry had not shown detectable levels of PrP^C in the brains of wild-type mice. Therefore, a Western blot analysisof synaptic fractions of wild-type mouse brains was performedand was compared with preparations of PrP^C-overexpressing transgenic animals. PrP^C was found to be enriched in the synaptic plasma membrane fractionin both wild-type and PrP^C-overexpressing mice. This was similar to the distribution ofother synaptic proteins, such as synaptotagmin and the NMDA-R1receptor subunit. In contrast to the synaptic vesicle proteinsynaptotagmin, which is more strongly enriched in the synapticvesicle fraction than in the synaptic plasma membrane fraction,PrP^C was more strongly enriched in the synaptic plasma membrane fraction,indicating that a predominant location of PrP^C on the synaptic vesicle membrane as supposed recently (Fournieret al., 1995) does not seem very likely. Also, the finding thattrypsinization of synaptosomes leads to a complete degradationof PrP^C while a synaptic vesicle protein remains intact further supportsthe notion that PrP^C is predominantly, if not exclusively, located on the surfaceof the synaptic plasmamembrane.

On the functional level, our previous electrophysiological investigations of inhibitory and excitatory synaptic transmissionin the cerebellum of Prnp^0/0 mice did not support the notion that PrP^C is involved in synaptic transmission under normal conditions(Herms et al., 1995). The findings we present here indicate thatprominent differences in synaptic transmission between wild-typeand Prnp^0/0 mice can be observed in certain biochemically defined conditions.The key result of our experiments is that bath application ofH₂O₂ induces a strong and sustained increase in the frequencyof sIPSCs in Purkinje cells of normal mice but not of Prnp^0/0 mice. In transgenic mouse strains in which the prion proteingene had been reintroduced on a Prnp^0/0 background, i.e., tg 35 and tg20 (PrP^C gene-reconstituted mice), all tested cells presented a strongand lasting increase of sIPSC frequency after H₂O₂ application.Therefore, the effect elicited by hydrogen peroxide is not unspecificbut is related to PrP^C expression in these animals (functional reconstitution). Thefact that the increase in sIPSC frequency was also observed inPurkinje cells of tg20 mice, which have been shown to overexpressPrP^C in neuronal cells excluding Purkinje cells, gives strong evidencethat it is the expression on the presynaptic plasma membrane ofthe interneuron that is responsible for the observed differencesin the response to H₂O₂ in the different transgeniclines.

How is the effect of H₂O₂ related to PrP^C expression? We propose that the different H₂O₂ responses of wild-type, Prnp^0/0, and transgenic mice that overexpress PrP^C (tg20 and tg35) are caused by the different amounts of copperlocated at the presynaptic plasma membrane. Metal ions, i.e.,copper and iron, decompose H₂O₂ to highly reactive oxygen radicalsat the site at which the metal ions are located (Halliwell, 1992).At the synapse, these radicals alter synaptic vesicle releasethrough an increase in the presynaptic calcium concentration (Pellmaret al., 1994; Pellmar, 1995) probably because of an alterationof intracellular calcium pools that are located close to the presynapticmembrane. Because an increase in the free calcium concentrationat the presynaptic membrane is known to increase the probabilityof synaptic vesicle release (Heidelberger et al., 1994), thisis the most likely explanation for the observed sIPSC and mIPSCfrequency increase after the application of H₂O₂ in wild-typemouse cerebellar Purkinje cells of the present study. The sIPSCfrequency increase after the application of H₂O₂ is significantlylower in Prnp^0/0 mice in which the amount of copper was found to be reduced insynaptosomes than in wild-type mice. In the transgenic mice inwhich PrP^C had been reintroduced, however, both the synaptosomal coppercontent and the H₂O₂ effect on sIPSC frequency were found to berescued.

Also, the IPSC amplitude was found to be altered by H₂O₂ application, but only in Prnp^0/0 mice and the transgenic mice, which highly overexpress PrP^C on the presynaptic side (tg20). Although a decrease of the IPSCamplitude was observed in Prnp^0/0 mice compared with wild-type mice, an increased was found inthe transgenic mice that overexpress PrP^C on the presynaptic side. Because tg20 mice do not express PrP^C in Purkinje cells, these two mouse lines differ only in the PrP^C expression on the presynaptic side of the interneuron-Purkinjecell synapse. A presynaptic cause therefore seems verylikely.

However, copper-binding by PrP^C at the presynaptic plasma membrane is probably not the only cause of the observed differencesin the synaptosomal copper content of wild-type and Prnp^0/0 mice. Synaptosomes include the presynaptic plasma membrane, aswell as parts of the postsynaptic plasma membrane, and they alsoinclude high amounts of presynaptic cytosol and organelles suchas mitochondria. Considering that several proteins in synaptosomesbind copper, the observed reduction of 50% in the copper concentrationof Prnp^0/0 mouse synaptosomes is too high to be only caused by a loss ofcopper that is bound to PrP^C. Indeed, we suppose that the copper bound to PrP^C contributes only very little to the overall copper content measuredin synaptosomes. This is supported by the finding that the transgenicline that overexpresses PrP^C (tg20) shows an increased response to H₂O₂ compared with wild-typemice but does not show a higher synaptosomal copperconcentration.

It therefore seems that the strong differences in the synaptosomal copper content of Prnp^0/0 and wild-type mice are caused by an alteration of copper uptakeinto synaptosomes by loss of PrP^C. Our working hypothesis is that PrP^C recaptures copper that is released into the synaptic cleft bysynaptic vesicle fusion (Hartter and Barnea, 1988). In Prnp^0/0 mice, copper is lost into the extracellular space and cannotbe taken up as effectively into the presynaptic cytosol in whichthe copper content is lastingly reduced. This may be the causeof the reduced activity of a cytosolic copper-dependent enzyme,the superoxide dismutase, observed in Prnp^0/0 mice (Brown et al., 1997b).

In addition, the loss of copper binding at the synaptic cleft through the loss of PrP^C at the synaptic membrane, which might lead to a slightly highercopper concentration in the extracellular fluid in Prnp^0/0 mice, may well be a relevant factor in explaining alterationsin the properties of the GABA_A receptor, as well as in hippocampallong-term potentiation (LTP), as has been described for Prnp^0/0 mice (Collinge et al., 1994; Manson et al., 1995; Whittingtonet al., 1995). The GABA_A receptor, as well as long-term potentiationin the hippocampus, have been shown recently to be affected bycopper concentrations of only 0.1-1 µM (Doreulee et al., 1997;Sharonova et al., 1998). Therefore, minor differences in the extracellularcopper concentration would cause alterations of the GABA_A receptorand of LTP. Because the physiological constitution of the extracellularfluid using brain slices in electrophysiological experiments mayvary considerably, differences in the experimental setup, suchas slice thickness, the position of the cell in the studied slice,the buffer used, and, in particular, higher temperatures withincreased oxidative stress, quite clearly influence results, dependingon the amount of PrP^C and copper present in the synapse in wild-type and Prnp^0/0 animals. Such differences may therefore explain why an alterationof the GABA_A receptor, as well as a diminished LTP in Prnp^0/0 mouse neurons, was not reproduced by other observers using slightlydifferent protocols, including lower temperatures (Herms et al.,1995; Lledo et al., 1996).

In conclusion, morphological and biochemical investigations of different PrP^C-transgenic mouse lines provide strong evidence of a predominantlysynaptic location of PrP^C. Electrophysiological studies indicate that PrP^C is a prominent copper-binding protein at the presynaptic plasmamembrane. Loss of PrP^C in Prnp^0/0 mice strongly affects the copper content in synaptosomes, indicatingthat PrP^C is involved in synaptic copper homeostasis. The exact functionof copper binding by PrP^C at the synaptic plasma membrane and its role in synaptic coppermetabolism, as well as in synaptic transmission, remain to beclarified.

  FOOTNOTES

Received May 27, 1999; revised July 26, 1999; accepted July 30, 1999.

This work was supported by BMBF (German Federal Ministry of Science and Technology) Grant KI 9461/8, Wilhelm-Sander-StiftungGrant 9343008, and Deutsche Forschungsgemeinschaft Grant KR 1561/2-1and Sonderforschungsbereich 406. We thank Charles Weissmann (Universityof Zürich) for Prnp^0/0, tg35, and tg20 mice, Dr. Christophe Pouzat for the program foranalysis of synaptic activity, and Dr. Bernhard Keller for helpfulcomments on thismanuscript.
Correspondence should be addressed to Dr. H. A. Kretzschmar, Georg-August Universität Göttingen, Robert-Koch-Strasse 40,37075 Göttingen,Germany.

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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