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Absence of spontaneous disease and comparative prion susceptibility of transgenic mice expressing mutant human prion proteins

MRC Prion Unit and Department of Neurodegenerative Disease, UCL Institute of Neurology, National Hospital for Neurology and Neurosurgery, Queen Square, London WC1N 3BG, UK

Correspondence
John Collinge
j.collinge{at}prion.ucl.ac.uk

	ABSTRACT

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Approximately 15 % of human prion disease is associated with autosomal-dominant pathogenic mutations in the prion protein (PrP) gene. Previous attempts to model these diseases in mice have expressed human PrP mutations in murine PrP, but this may have different structural consequences. Here, we describe transgenic mice expressing human PrP with P102L or E200K mutations and methionine (M) at the polymorphic residue 129. Although no spontaneous disease developed in aged animals, these mice were readily susceptible to prion infection from patients with the homotypic pathogenic mutation. However, while variant Creutzfeldt–Jakob disease (CJD) prions transmitted infection efficiently to both lines of mice, markedly different susceptibilities to classical (sporadic and iatrogenic) CJD prions were observed. Prions from E200K and classical CJD M129 homozygous patients, transmitted disease with equivalent efficiencies and short incubation periods in human PrP 200K, 129M transgenic mice. However, mismatch at residue 129 between inoculum and host dramatically increased the incubation period. In human PrP 102L, 129M transgenic mice, short disease incubation periods were only observed with transmissions of prions from P102L patients, whereas classical CJD prions showed prolonged and variable incubation periods irrespective of the codon 129 genotype. Analysis of disease-related PrP (PrP^Sc) showed marked alteration in the PrP^Sc glycoform ratio propagated after transmission of classical CJD prions, consistent with the PrP point mutations directly influencing PrP^Sc assembly. These data indicate that P102L or E200K mutations of human PrP have differing effects on prion propagation that depend upon prion strain type and can be significantly influenced by mismatch at the polymorphic residue 129.

Published online ahead of print on 8 December 2008 as DOI 10.1099/vir.0.007930-0.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

 
Inherited prion diseases (IPDs) are fatal neurodegenerative disorders caused by autosomal-dominant mutations in the human PrP gene (PRNP), and constitute about 15 % of all human prion disease (Collinge, 2001, 2005; Kovacs et al., 2002; Wadsworth et al., 2003; Mead, 2006). Over 30 mutations have been identified, but the precise biochemical mechanisms that lead to disease remain unknown.

According to the ‘protein-only’ hypothesis (Griffith, 1967), an abnormal isoform of host-encoded cellular prion protein (PrP^C) is the principal, and possibly the sole, constituent of the transmissible agent or prion (Prusiner, 1982; Collinge & Clarke, 2007). This hypothesis proposes that the central pathogenic process is the conversion of PrP^C to a disease-related isoform, PrP^Sc, through a conformational change occurring either spontaneously or during interaction with exogenous PrP^Sc. PrP^Sc consists of aggregated misfolded PrP and distinct prion strains are thought to be composed of different polymeric forms of PrP (for recent review see Collinge & Clarke, 2007). Importantly, IPDs may also be experimentally transmissible and it is thought that pathogenic mutations in PRNP predispose mutant PrP^C to convert spontaneously to a pathogenic isoform (Collinge & Palmer, 1992; Collinge, 2005; Collinge & Clarke, 2007). While patients with IPD have traditionally been classified by the clinicopathological syndromes of Gerstmann–Sträussler–Scheinker disease (GSS), Creutzfeldt–Jakob disease (CJD) or fatal familial insomnia (FFI), the advent of molecular genetic diagnosis led to the recognition of considerable phenotypic heterogeneity even within families with the same PRNP mutation (Collinge et al., 1989, 1990, 1992; Mallucci et al., 1999; Kovacs et al., 2002; Wadsworth et al., 2006) and subclassification of IPD by pathogenic mutation was proposed (Collinge et al., 1992; Collinge & Prusiner, 1992).

The mutation at codon 200 of PRNP, which results in a glutamic acid substitution by lysine (E200K) in PrP, is one of the most prevalent, being responsible for the high incidence of CJD amongst Libyan Jews and in areas of Slovakia and Chile, and is recognized in many other countries (Goldfarb et al., 1990, 1991; Hsiao et al., 1991; Brown et al., 1992; Collinge et al., 1993; Kovacs et al., 2002). Families with the E200K mutation demonstrate varied clinical symptoms including uncommon features such as fatal insomnia, pruritus and demyelinating peripheral neuropathy or protracted dementia without other distinguishing characteristics (Chapman et al., 1993). Indeed, this form of IPD can present clinically and pathologically like classic sporadic CJD (Chapman et al., 1993), and although PRNP E200K homozygotes do not seem to differ in clinical features from heterozygotes, a statistically significant younger age at disease onset was found for homozygotes (Simon et al., 2000). Penetrance for the E200K mutation is age dependent and approaches 100 % by 85 years of age (Chapman et al., 1993).

A proline to leucine substitution at codon 102 (P102L) of human PrP is the most common mutation associated with the GSS phenotype and was first reported in 1989 (Hsiao et al., 1989). Many other families have now been documented worldwide (Kovacs et al., 2002), including the original Austrian family reported by Gerstmann, Sträussler and Scheinker in 1936 (Kretzschmar et al., 1991; Hainfellner et al., 1995). Progressive ataxia is the dominant clinical feature, with dementia and pyramidal features occurring later in a disease course typically much longer than that of classical CJD. However, marked variability at both the clinical and neuropathological levels is apparent, with some patients developing a classical CJD-like phenotype with early and rapidly progressive dementia (Hainfellner et al., 1995; Barbanti et al., 1996; Majtenyi et al., 2000; Wadsworth et al., 2006; Kretzschmar et al., 1992; Webb et al., 2008). A recent study indicates that differential recruitment of wild-type PrP into PrP^Sc may contribute to phenotypic variability in atypical cases (Wadsworth et al., 2006).

Polymorphism at residue 129 of human PrP [where either methionine (M) or valine (V) can be encoded] not only affects susceptibility to sporadic and acquired human prion diseases (Palmer et al., 1991; Collinge et al., 1991; Lee et al., 2001; Mead et al., 2003), but can affect the age of onset and also modify the phenotypes of IPDs (Baker et al., 1991; Poulter et al., 1992; Goldfarb et al., 1992; Mead et al., 2006).

Early attempts to transmit IPDs in non-human primates (Brown et al., 1994) and wild-type mice (Tateishi et al., 1996) resulted in poor transmission rates, resulting in the important issue of whether or not all IPDs are experimentally transmissible being unresolved (Collinge, 1997).

Transgenic mice expressing high levels of mouse PrP 101L (equivalent to 102L in human PrP) spontaneously developed neurological dysfunction at 166 days of age (Hsiao et al., 1990). PrP^Sc levels were low or undetectable, and brain extracts from affected mice did not transmit CNS degeneration to wild-type mice, but transmission to hamsters and Tg(GSSPrP)196 mice, expressing lower levels of the same mutant transgene product, was reported (Hsiao et al., 1994; Telling et al., 1996a). These Tg(GSSPrP)196 mice have subsequently been reported to develop spontaneous disease at advanced age (Tremblay et al., 2004; Nazor et al., 2005). It therefore remains debateable as to whether prions had been generated in these transgenic mice or this simply represents acceleration of a spontaneous neurodegenerative disease already poised to occur in these mice (Nazor et al., 2005). Others generated transgenic mice expressing endogenous levels of mouse PrP 101L by the gene knock-in approach (Manson et al., 1999). These mice did not develop spontaneous neurodegeneration but were reported to show greater susceptibility to human P102L prions than wild-type mice (Barron et al., 2001).

However, we consider it essential to study this and other human pathogenic mutations in human PrP, rather than in mouse PrP where the mutation may have different structural consequences. With respect to such models it is important to demonstrate that human PrP is functionally active and can participate in prion propagation and pathogenesis in mouse cells. Human PrP can rescue a PrP null phenotype in mice (Whittington et al., 1995), confirming it is functionally active and human prions can replicate in transgenic mice expressing only human PrP, which develop spongiform neurodegeneration (Collinge et al., 1995).

Importantly, there are examples of IPD where the amino acid change thought to be pathogenic is found as a normal variant in other mammalian species (Butefisch et al., 2000; Lysek et al., 2004; Colucci et al., 2006). There is also direct experimental evidence that a human PRNP mutation on a mouse background would not necessarily have the same structural consequences in the expressed protein. The introduction of a tryptophan residue at amino acid position 175 in place of the native phenylalanine has been successfully used as an optical probe for studying the folding dynamics of the recombinantly expressed mouse PrP (Wildegger et al., 1999). The introduction of this probe had no measurable effect on the stability of the protein. However, in stark contrast, when we introduced the same mutation into the human PRNP gene, the resultant recombinant PrP was unable to fold into the native conformation (T. Hart, G. J. Jackson, A. R. Clarke & J. Collinge, unpublished data). The profoundly dissimilar consequences of the same mutation in mouse and human PrP questions the whole approach of modelling human pathogenic mutations on non-homologous PrP sequences from other species. In particular, the destabilizing effects measured in a mouse protein cannot be assumed to be equivalent in the human protein. The present study differs from all previous reports because we have investigated the biological properties of naturally occurring mutations in human PrP itself expressed in transgenic mice.

We have now generated two transgenic mouse lines that are both homozygous for the human PrP^102L,129M expressing transgene on a homozygous mouse PrP gene (Prnp) null background (HuPrP^102L,129M+/+ Prnp^o/o). Similarly, we have generated two further transgenic lines that are both homozygous for human PrP^200K,129M transgenes, again on a Prnp^o/o background (HuPrP^200K,129M+/+ Prnp^o/o). Here, we report the relative susceptibilities of these transgenic mice to classical (sporadic and iatrogenic) CJD prions, homotypic IPD isolates and variant (v) CJD prions.

	METHODS

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Transgene construction.
Briefly, the 759 bp human PrP ORF was amplified by PCR with Pfu polymerase from human genomic DNA with appropriate mutations, using forward primer 5'-GTCGACCAGTCATTATGGCGAACCTT-3' and reverse primer 5'-CTCGAGAAGACCTTCCTCATCCCACT-3'. Restriction sites SalI and XhoI (underlined) were introduced in the forward and reverse primers, respectively, for use in subsequent cloning steps. The blunt-ended PCR fragments generated by Pfu polymerase were subcloned into SmaI-digested pSP72 vector and sequenced to ensure that no spurious alterations have been introduced by the PCR other than the expected existing point mutations. The mutant human PrP ORFs with the appropriate point mutation confirmed were then isolated by using SalI and XhoI. Subsequent subcloning into the cosmid vector SHaCosTt (Scott et al., 1989) and preparation of high quality DNA of the insert was as described previously (Asante et al., 2002).

Microinjection.
The purified PRNP transgenes for P102L and E200K both with M at polymorphic codon 129 were microinjected (Hogan et al., 1994) into single cell eggs of a strain of mice (FVBxSV129xC57) in which the murine PrP gene has been ablated. This was achieved by back-crossing ZH1 Prnp knockout line (Bueler et al., 1992) to FVB/N for five generations, breeding out Prnp and restoring homozygosity of the knockout allele. The injected eggs were cultured to the two-cell stage and then surgically transferred to F1 (CBAxC57BL/6) recipient females. Two homozygous lines were established for P102L designated Tg27 and Tg33 with mutant transgene expression levels of three and one and a half times, respectively, compared with pooled normal human brain levels. Similarly, two homozygous lines were established for E200K designated Tg23 and Tg49 with relative expression levels of three- and twofold, respectively.

Genotyping.
Tail biopsies were taken from putative transgenics and screened by PCR using human PrP-specific primers (5'-GTGGCCAGATGGAGTGACCTGGGCCTC-3' and 5'-GGCACTTCCCAGCATGTAGCCG-3'). Founders were confirmed by Southern blotting using a 900 bp 3' UTR fragment as a radiolabelled probe. Lines were bred to homozygosity and 20 mice were set aside for long-term neurological observation.

Transmission studies.
All procedures were carried out in a microbiological containment level III facility with strict adherence to safety protocols. A panel of inocula comprising four inherited P102L, three sporadic and three iatrogenic CJD cases were used for the 102L transgenic mice. For the 200K transgenic mice, two inherited E200K and one iatrogenic CJD inocula were used. Inocula were prepared from the brain of neuropathologically confirmed cases of sporadic and inherited CJD with consent from relatives and with the approval from the Institute of Neurology/National Hospital for Neurology and Neurosurgery Local Research Ethics Committee. Mice were anaesthetized with a mixture of halothane and O₂, and intracerebrally inoculated into the right parietal lobe with 30 µl of a 1 % (w/v) brain homogenate prepared in PBS. All mice were thereafter examined daily for clinical signs of prion disease. Mice were killed if exhibiting any signs of distress or once a diagnosis of prion disease was established.

Neuropathology and immunohistochemistry.
Neuropathology and immunohistochemical analyses were done as described previously (Asante et al., 2002, 2006) with the exception that abnormal PrP accumulation was examined using anti-PrP monoclonal antibody ICSM 18 (D-Gen Ltd) for P102L detection, and ICSM 35 (D-Gen Ltd) was used for E200K detection because the latter antibody does not recognize human PrP 102L (Wadsworth et al., 2006). Appropriate controls were used throughout.

Immunoblotting.
Brain homogenates (10 %, w/v) were prepared in Dulbecco's PBS lacking Ca²⁺ or Mg²⁺ ions (D-PBS) by serial passage through needles of decreasing diameter. Aliquots were analysed with or without proteinase K digestion (50 or 100 µg ml^–1 final protease concentration, 1 h, 37 °C) by electrophoresis and immunoblotting as described previously (Wadsworth et al., 2001, 2008; Hill et al., 2003, 2006). Blots were probed with anti-PrP monoclonal antibody 3F4 (Kascsak et al., 1987). For quantification and analysis of PrP glycoforms, blots were developed in chemifluorescent substrate (AttoPhos; Promega) and visualized on a Storm 840 phosphoimager (Molecular Dynamics) (Wadsworth et al., 2001; Hill et al., 2003, 2006). Quantification of PrP^Sc glycoforms was performed using ImageQuant software (Molecular Dynamics).

	RESULTS

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Transgenic mice expressing HuPrP 102L or 200K do not develop spontaneous disease
We generated two homozygous transgenic mouse lines designated Tg(HuPrP^102L,129M+/+ Prnp^o/o)-27 and Tg(HuPrP^102L,129M+/+ Prnp^o/o)-33 that expressed human PrP 102L,129M at three and one and a half times the human endogenous PrP^C levels, respectively (Table 1), but not mouse PrP.

We also established two homozygous transgenic lines designated Tg(HuPrP^200K,129M+/+ Prnp^o/o)-23 and Tg(HuPrP^200K,129M+/+ Prnp^o/o)-49 that expressed human PrP 200K,129M at three and two times, respectively (Table 1), compared with endogenous PrP^C levels in a pooled normal human brain homogenate. We again set aside 20 mutant mice from both 200KK (homozygous for glutamic acid to lysine 200 mutation) lines and observed them long-term. Mice that died earlier than 400 days from intercurrent illnesses showed no evidence of prion-related neuropathology. Again, mice in the cohort survived to an advanced age without clinical or neuropathological signs of prion disease or detectable PrP^Sc, with the oldest mouse living to more than 955 days (mean survival shown in Table 1). For both 102LL and 200KK mutant PRNP transgenic lines, Western blot analysis (data not shown) of samples from the brain of uninoculated mice showed equivalent proportions of di-, mono- and non-glycosylated PrP to that seen in Tg35 and Tg45 transgenic mice expressing wild-type human PrP 129M (Asante et al., 2002). These data establish that the PRNP point mutations do not selectively destabilize a particular PrP glycoform. It is worth noting that Tg45 mice expressing human PrP 129M at four times wild-type levels do not develop spontaneous disease at a similar age (Asante et al., 2002).

Transgenic mice expressing HuPrP 102L are more susceptible to prions from patients with IPD (P102L) than to classical CJD prions
To assess the susceptibility of human PrP 102L-expressing transgenic mice to human prions, we inoculated groups of Tg27 and Tg33 mice intracerebrally with isolates from patients with classical CJD and IPD (P102L). Clinical disease with high attack rates and short incubation periods ranging from 185 to 191 days accompanied the transmission of four different IPD P102L cases to Tg27 transgenic mice (Table 2). In sharp contrast, challenge of Tg27 mice with four classical CJD isolates, all resulted in incomplete clinical attack rates and prolonged and highly variable incubation periods ranging from 342 to 717 days. However, with the exception of one inoculum, I026, where two mice were not affected, all sporadic and iatrogenic CJD-inoculated mice were scored as positive for prion infection by one or more of the following criteria: typical clinical signs, presence of PrP^Sc on Western blot analysis or abnormal PrP immunohistochemistry (Table 2).

View larger version (125K): [in this window] [in a new window]   Fig. 2. Neuropathological analysis of transgenic mouse brain by PrP immunohistochemistry. Anti-PrP monoclonal antibody ICSM 18 was used for the 102LL transgenic brains, and ICSM 35 was used for the 200KK transgenic brains because ICSM 35 does not detect mutant 102L PrP (Wadsworth et al., 2006). Upper panels (a–c and g–i) show regional distributions of PrP plaque deposition in 102LL 129M Tg27 and 200KK 129M Tg49 transgenic mice challenged with the various human prion inocula with the aetiologies indicated above each panel; synaptic type PrP deposits (pink), discrete PrP plaque deposits (red), blue box in the sketch denotes the area from which the PrP stained sections are derived. Panels (d), (e) and (f) represent PrP monoclonal antibody ICSM 18 immunohistochemical staining in 102LL 129M Tg27 transgenic mice challenged, respectively, with sporadic CJD, P102L and vCJD prions. Panels (j), (k) and (l) represent PrP monoclonal antibody ICSM 35 immunohistochemical staining in 200KK M129 Tg49 transgenic mice challenged, respectively, with IPD E200K-129MM, E200K-129VV and vCJD inocula. Inserts in panels (f) and (l) show examples of florid plaques associated with the neuropathology of vCJD prion transmissions in these mutant mice. Bar, panels (d)–(f) and (j)–(l)=200 µm.

IPD E200K-129MM inoculum (I1091) transmitted clinical disease to 8/8 of Tg23 mice, with a short mean incubation period of 184±3 days (Table 4). In sharp contrast, the second IPD E200K inoculum (I093) (E200K-129VV) produced clinical disease in only 1/4 inoculated mice with a relatively prolonged incubation period of 437 days. There was however 100 % total infection rate because the three clinically asymptomatic mice, which died at 410, 518 and 538 days post-inoculation, had clear evidence of subclinical prion infection as determined either by PrP immunohistochemical or Western blot analysis (Table 4). The transmission properties of classical CJD in Tg23 mice were distinct from that observed in human PrP 102L-expressing transgenic mice. Here, iatrogenic CJD 129MM inoculum (I026) produced 100 % clinical attack rate and with relatively short mean incubation period of 184±7 days that was remarkably similar to the mean incubation period for IPD E200K-129MM inoculum I1091. These data suggest that, providing there is homology at residue 129 between the inoculum and the host PrP, the E200K mutation does not introduce a transmission barrier for classical CJD prions.

PrP glycoform profiles in transgenic mice challenged with classical CJD and IPD prions
Within the framework of the protein-only hypothesis, the different phenotypes associated with prion strains are thought to be determined by the propagation of distinct PrP^Sc isoforms with divergent physico-chemical properties (Bessen & Marsh, 1994; Collinge et al., 1996b; Telling et al., 1996b; Safar et al., 1998; Prusiner, 1998; Hill & Collinge, 2000; Collinge, 2001; Gambetti et al., 2003; Collinge & Clarke, 2007). IPDs with P102L and E200K mutations are associated with a unique PrP^Sc glycoform ratio that differs significantly from those seen in classical CJD and vCJD (Collinge et al., 1996b; Hill et al., 2003, 2006; Wadsworth et al., 2006). We therefore analysed PrP^Sc glycoform ratios propagated in human PrP 102L- and 200K-expressing transgenic mice challenged with a range of human prions. Mice inoculated with either IPD isolates or classical CJD isolates propagated PrP^Sc with a predominance of both di- and monoglycosylated PrP (Fig. 1). This finding is of particular interest in recipients of classical CJD prions where a change in PrP^Sc glycoform ratio is apparent on transmission (see Fig. 1b lanes 3 and 6; and Table 6). While the primary transmission data suggest that there are statistically significant differences in the glycoform ratios of PrP^Sc propagated in human PrP 102L- and 200K-expressing transgenic mice inoculated with IPD isolates (data not shown) or classical CJD prions (Table 6), further subpassage to transgenic mice expressing either mutant or wild-type PrP will be required to fully interpret this observation because of the heterogeneous nature of the primary IPD inocula from patients' brains used in these primary transmissions (Hill et al., 2006; Wadsworth et al., 2006; Wadsworth & Collinge, 2007).

View larger version (66K): [in this window] [in a new window]   Fig. 1. Immunoblot analysis highlighting the PrPSc types propagated in brains of transgenic mice. Mice were inoculated with classical CJD and prions from patients with IPD P102L and E200K. (a) Immunoblots comparing transmission of IPD P102L prions and classical CJD to 102LL 129M Tg27 and Tg33 transgenic mice. (b) Immunoblots comparing transmission of human isolates from E200K-129MM, E200K-129VV and classical CJD to 200KK 129M Tg23 transgenic mice. (c) Immunoblots comparing transmission of IPD E200K-129MM, P200K-129VV and classical CJD prions to 200KK 129M Tg49 transgenic mice. (d) Immunoblots comparing transmission of vCJD prions to transgenic lines expressing human PrP. The provenance of each brain sample is designated above each lane. Immunoblots were analysed by enhanced chemiluminescence with anti-PrP antibody 3F4.

Transmission of vCJD prions to Tg27 mice resulted in only 2/11 clinical attack rate with prolonged incubation periods greater than 482 days post-inoculation (Table 2), but 11/11 total infection rate (positive either by clinical scoring, immunoblot or immunohistochemistry), mirroring transmission properties of the same vCJD inoculum in homozygous human PrP 129MM-expressing Tg35 and Tg45 mice (Asante et al., 2002). Similarly, transmission of vCJD to Tg23 and Tg49 transgenic mice resulted in 3/6 and 2/6 clinical attack rates, respectively, and with prolonged incubation periods (Tables 4 and 5), and these were again accompanied by 100 % total infection rate in both lines, as determined either by clinical scoring, Western blot analysis or immunohistochemistry. Affected Tg27 mice propagated PrP^Sc that was closely similar to type 4 PrP^Sc present in the vCJD inoculum (Fig. 1d, lanes 1 and 3) and distinct from type 5 PrP^Sc seen in vCJD-inoculated Tg152 mice expressing human PrP 129V (Hill et al., 1997; Wadsworth et al., 2004) (Fig. 1d, lane 2). In keeping with this finding, vCJD-inoculated Tg27 mice showed neuropathological changes that were characteristic of the vCJD prion strain with extensive plaque deposition many of which were of the florid type (Fig. 2c, f).

In vCJD challenged human PrP 200K-expressing transgenic mice Tg23 (data not shown) and Tg49 (Fig. 2i, l), abundant florid plaques were also observed that were indistinguishable from the florid plaques generated in transgenic mice expressing wild-type human PrP 129MM, Tg35 or Tg45 (Asante et al., 2002). Interestingly, the lower human PrP 200K-129M-expressing Tg49 line had a higher PrP plaque load than Tg23 mice, suggesting that PrP plaque density may be related to the kinetics of PrP^Sc formation. Notably, however, both human PrP 200K-129M-expressing lines Tg23 and Tg49 propagated PrP^Sc with a slightly lower molecular mass fragment size than type 4 PrP^Sc seen in the vCJD inoculum (Fig. 1d, lanes 4 and 5). We have provisionally designated this new PrP^Sc isoform, that generates proteinase K-resistant fragments sharing the glycoform ratio of types 4 and 5 PrP^Sc but with a smaller fragment size than type 4, as human PrP^Sc type 8. Serial passage studies will be required to establish if, like type 5 PrP^Sc, this novel PrP^Sc type represents a distinct vCJD-derived prion strain. In this regard, it will be interesting to see whether this distinct PrP^Sc conformer, that is associated with abundant florid plaques in human PrP 200K-expressing transgenic mice (Fig. 2i, l), can be maintained on subpassage in transgenic mice expressing wild-type human PrP.

	DISCUSSION

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In these studies, we have used transgenic mice homozygous for two different human PrP mutations and devoid of murine PrP, in order to allow a comparative study of the transmission properties of PRNP mutations in the absence of the confounding effects of endogenous murine PrP. Our study differs from previous reports (Hsiao et al., 1990; Hegde et al., 1998; Chiesa et al., 1998; Manson et al., 1999), in that we have modelled PRNP disease-associated mutations on human PrP, rather than superimposing the human mutations on rodent PrP. This is particularly important because destabilizing effects measured in a mouse protein cannot be assumed to be equivalent in the human protein (Wildegger et al., 1999; T. Hart, G. J. Jackson, A. R. Clarke & J. Collinge, unpublished data).

Our data show that while the P102L mutation is permissive to homotypic IPD P102L prions, there appears to be a barrier limiting the transmission of classical CJD prions. In contrast, the E200K mutation is equally permissive to homotypic IPD E200K and classical CJD prions, providing there is no mismatch at PRNP codon 129. Neither mutation appears to influence the propagation of the vCJD prion strain.

Previously we have shown that cases of IPD caused by the PRNP point mutations P102L, D178N and E200K have a unique PrP^Sc glycoform ratio following proteinase K digestion, which differs significantly from PrP^Sc glycoform ratios observed in sporadic, iatrogenic and vCJD or IPD caused by octapeptide repeat insertional mutations (Hill et al., 2006; Wadsworth et al., 2006). These data suggested that point mutations in PRNP either destabilize non-glycosylated PrP, in turn reducing its relative abundance (Petersen et al., 1996), or directly dictate the stoichiometry and packing order of the three PrP glycoforms into disease-related fibrils or other aggregates. The latter explanation is consistent with a conformational selection model of prion transmission barriers (Collinge, 1999; Hill & Collinge, 2003; Collinge & Clarke, 2007) that predicts that coding changes in PrP act to specify structural preferences for disease-related PrP isoforms. The full spectrum of effects that different pathogenic PRNP mutations may have still remains unclear (Hill et al., 2006).

Importantly, our data now show that the PrP^Sc glycoform ratio of classical CJD prions is not maintained on passage in transgenic mice expressing PRNP 102L or 200K point mutations. Instead PrP^Sc propagates with a glycoform ratio closely similar to those seen in patients with P102L and E200K IPD that is significantly different from the PrP^Sc types present in the classical CJD inoculum. These data support the hypothesis that prion strains propagated in IPDs are distinct from those propagated in classical (sporadic and iatrogenic) CJD (Hill et al., 2006). As equivalent proportions of the PrP glycoforms are seen in PrP^C expressed in uninoculated wild-type or mutant PRNP transgenic mice, this change in PrP^Sc glycoform ratio is consistent with the PRNP point mutations acting to directly dictate the stoichiometry and packing order of the three PrP glycoforms into disease-related fibrils or other aggregates (Hill et al., 2006). Furthermore, previous immunoprecipitation studies using a panel of monoclonal antibodies suggested that the proportion of each glycoform incorporated into PrP^Sc is probably controlled in a strain-specific manner (Khalili-Shirazi et al., 2005).

The interpretation of primary transmission data for IPD isolates is complicated by the heterogeneous composition of disease-related PrP isoforms that may be present in the primary inoculum (Hill et al., 2006; Wadsworth et al., 2006; Wadsworth & Collinge, 2007). For example in P102L IPD, it is now apparent that three isoforms of protease-resistant PrP with divergent physico-chemical properties can be propagated. Two distinct abnormal conformers derived from PrP P102L generate protease-resistant fragments of either approximately 21–30 or 8 kDa (Parchi et al., 1998; Piccardo et al., 1998, 2007; Muramoto et al., 2000; Hill et al., 2006; Wadsworth et al., 2006), while abnormal conformers of wild-type PrP appear to generate proteolytic fragments of only approximately 21–30 kDa (Wadsworth et al., 2006). Glycoform ratios of approximately 21–30 kDa proteolytic fragments generated from PrP P102L and wild-type PrP are not only distinct from each other, but are also distinct from those generated from wild-type PrP in sporadic or acquired CJD (Wadsworth et al., 2006). Differences in neuropathological targeting of these distinct disease-related PrP species, together with differences in their abundance and potential neurotoxicity, provide a molecular mechanism for generation of multiple phenotypes in P102L IPD (Wadsworth et al., 2006; Piccardo et al., 2007). Propagation of particular PrP^Sc isoforms in a new host will also be determined by host genetic background, PRNP sequence and prion strain type (Collinge & Clarke, 2007). These data have significant implications for interpreting the transmission properties of IPD isolates in both conventional and transgenic mice and may in part explain the historical differences seen in previous transmissions of IPD isolates (Brown et al., 1994; Tateishi et al., 1996). Serial passage studies of the prion isolates generated here should help to clarify the major influencing factors limiting the transmission of IPD, and how many strains may be associated with IPDs.

	ACKNOWLEDGEMENTS

 
We thank our biological service team for animal care and R. Young for the preparation of figures. We are grateful to P. Jat for constructive comments on the manuscript. We thank patients and their families for consenting to the use of human tissues in this research and colleagues in neuropathology for provision of tissues. This research was initiated with funding from the Wellcome Trust and has been supported by the Medical Research Council (UK) and the European Union. Conflict of interest statement: J. C. is a Director and J. C. and J. D. F. W. are shareholders and consultants of D-Gen Ltd, an academic spin-out company working in the field of prion disease diagnosis, decontamination and therapeutics. D-Gen markets the ICSM 18 and ICSM 35 antibodies used in this study.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

 
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Received 15 October 2008; accepted 2 December 2008.

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