Tanya Seward

Transmission of Prions from Mule Deer and Elk with Chronic Wasting Disease to Transgenic Mice Expressing Cervid PrP

ABSTRACT We generated mice expressing cervid prion protein to produce a transgenic system simulating chronic wasting disease (CWD) in deer and elk. While normal mice were resistant to CWD, these transgenic mice uniformly developed signs of neurological dysfunction ∼230 days following intracerebral inoculation with four CWD isolates. Inoculated transgenic mice homozygous for the transgene array developed disease after ∼160 days. The brains of sick transgenic mice exhibited widespread spongiform degeneration and contained abnormal prion protein and abundant amyloid plaques, many of which were florid plaques. Transmission studies indicated that the same prion strain caused CWD in the analyzed mule deer and elk. These mice provide a new and reliable tool for detecting CWD prions.

Immunodetection of disease‐associated mutant PrP, which accelerates disease in GSS transgenic mice

The absence of infectivity‐associated, protease‐resistant prion protein (PrPSc) in the brains of spontaneously sick transgenic (Tg) mice overexpressing PrP linked to Gerstmann–Sträussler Scheinker syndrome, and the failure of gene‐targeted mice expressing such PrP to develop disease spontaneously, challenged the concept that mutant PrP expression led to spontaneous prion production. Here, we demonstrate that disease in overexpressor Tg mice is associated with accumulation of protease‐sensitive aggregates of mutant PrP that can be immunoprecipitated by the PrPSc‐specific monoclonal antibody designated 15B3. Whereas Tg mice expressing multiple transgenes exhibited accelerated disease when inoculated with disease‐associated mutant PrP, Tg mice expressing mutant PrP at low levels failed to develop disease either spontaneously or following inoculation. These studies indicate that inoculated mutant PrP from diseased mice promotes the aggregation and accumulation of pre‐existing pathological forms of mutant PrP produced as a result of transgene overexpression. Thus, while pathological mutant PrP possesses a subset of PrPSc characteristics, we now show that the attribute of prion transmission suggested by previous studies is more accurately characterized as disease acceleration.

Prion Strain Mutation Determined by Prion Protein Conformational Compatibility and Primary Structure

CWD Strain Variation So-called prion diseases are fatal neurogenerative disorders that include chronic wasting disease (CWD) found in deer and other cervids. Prion diseases are thought to be caused by infectious proteins (prions) in the absence of associated infectious DNA. Nevertheless, prion strains have been isolated that can mutate in the absence of nucleic acids, and these strain properties control the ability of prions to cross species barriers. Angers et al. (p. 1154, published online 13 May; see the Perspective by Collinge) address the issue of strain variation in the context of CWD. Whereas the host range of this contagious disease continues to expand, the prevalence of CWD strains has not been determined. Understanding CWD strain variation may be important in predicting and preventing any future risks to human health. The stability of two related strains is influenced by a species-specific amino acid difference in deer and elk prions. Prions are infectious proteins composed of the abnormal disease-causing isoform PrPSc, which induces conformational conversion of the host-encoded normal cellular prion protein PrPC to additional PrPSc. The mechanism underlying prion strain mutation in the absence of nucleic acids remains unresolved. Additionally, the frequency of strains causing chronic wasting disease (CWD), a burgeoning prion epidemic of cervids, is unknown. Using susceptible transgenic mice, we identified two prevalent CWD strains with divergent biological properties but composed of PrPSc with indistinguishable biochemical characteristics. Although CWD transmissions indicated stable, independent strain propagation by elk PrPC, strain coexistence in the brains of deer and transgenic mice demonstrated unstable strain propagation by deer PrPC. The primary structures of deer and elk prion proteins differ at residue 226, which, in concert with PrPSc conformational compatibility, determines prion strain mutation in these cervids.

Calpain-dependent Endoproteolytic Cleavage of PrPSc Modulates Scrapie Prion Propagation

Previous studies using post-mortem human brain extracts demonstrated that PrP in Creutzfeldt-Jakob disease (CJD) brains is cleaved by a cellular protease to generate a C-terminal fragment, referred to as C2, which has the same molecular weight as PrP-(27–30), the protease-resistant core of PrPSc (1). The role of this endoproteolytic cleavage of PrP in prion pathogenesis and the identity of the cellular protease responsible for production of the C2 cleavage product has not been explored. To address these issues we have taken a combination of pharmacological and genetic approaches using persistently infected scrapie mouse brain (SMB) cells. We confirm that production of C2 is the predominant cleavage event of PrPSc in the brains of scrapie-infected mice and that SMB cells faithfully recapitulate the diverse intracellular proteolytic processing events of PrPSc and PrPC observed in vivo. While increases in intracellular calcium (Ca2+) levels in prion-infected cell cultures stimulate the production of the PrPSc cleavage product, pharmacological inhibitors of calpains and overexpression of the endogenous calpain inhibitor, calpastatin, prevent the production of C2. In contrast, inhibitors of lysosomal proteases, caspases, and the proteasome have no effect on C2 production in SMB cells. Calpain inhibition also prevents the accumulation of PrPSc in SMB and persistently infected ScN2A cells, whereas bioassay of inhibitor-treated cell cultures demonstrates that calpain inhibition results in reduced prion titers compared with control-treated cultures assessed in parallel. Our observations suggest that calpain-mediated endoproteolytic cleavage of PrPSc may be an important event in prion propagation.

Accelerated High Fidelity Prion Amplification Within and Across Prion Species Barriers

Experimental obstacles have impeded our ability to study prion transmission within and, more particularly, between species. Here, we used cervid prion protein expressed in brain extracts of transgenic mice, referred to as Tg(CerPrP), as a substrate for in vitro generation of chronic wasting disease (CWD) prions by protein misfolding cyclic amplification (PMCA). Characterization of this infectivity in Tg(CerPrP) mice demonstrated that serial PMCA resulted in the high fidelity amplification of CWD prions with apparently unaltered properties. Using similar methods to amplify mouse RML prions and characterize the resulting novel cervid prions, we show that serial PMCA abrogated a transmission barrier that required several hundred days of adaptation and subsequent stabilization in Tg(CerPrP) mice. While both approaches produced cervid prions with characteristics distinct from CWD, the subtly different properties of the resulting individual prion isolates indicated that adaptation of mouse RML prions generated multiple strains following inter-species transmission. Our studies demonstrate that combined transgenic mouse and PMCA approaches not only expedite intra- and inter-species prion transmission, but also provide a facile means of generating and characterizing novel prion strains.

Chronic Wasting Disease Prions in Elk Antler Velvet

Residue 226 of cervid prion proteins may be a determinant of CWD pathogenesis.

The elk PRNP codon 132 polymorphism controls cervid and scrapie prion propagation.

The elk prion protein gene (PRNP) encodes either methionine (M) or leucine (L) at codon 132, the L132 allele apparently affording protection against chronic wasting disease (CWD). The corresponding human codon 129 polymorphism influences the host range of bovine spongiform encephalopathy (BSE) prions. To fully address the influence of this cervid polymorphism on CWD pathogenesis, we created transgenic (Tg) mice expressing cervid PrPC with L at residue 132, referred to as CerPrPC-L132, and compared the transmissibility of CWD prions from elk of defined PRNP genotypes, namely homozygous M/M or L/L or heterozygous M/L, in these Tg mice with previously described Tg mice expressing CerPrPC-M132, referred to as Tg(CerPrP) mice. While Tg(CerPrP) mice were consistently susceptible to CWD prions from elk of all three genotypes, Tg(CerPrP-L132) mice uniformly failed to develop disease following challenge with CWD prions. In contrast, SSBP/1 sheep scrapie prions transmitted efficiently to both Tg(CerPrP) and Tg(CerPrP-L132) mice. Our findings suggest that the elk 132 polymorphism controls prion susceptibility at the level of prion strain selection and that cervid PrP L132 severely restricts propagation of CWD prions. We speculate that the L132 polymorphism results in less efficient conversion of CerPrPC-L132 by CWD prions, an effect that is overcome by the SSBP/1 strain. Our studies show the accumulation of subclinical levels of CerPrPSc in aged asymptomatic CWD-inoculated Tg(CerPrP-L132) mice and also suggests the establishment of a latent infection state in apparently healthy elk expressing this seemingly protective allele.

Intrinsic muscle clock is necessary for musculoskeletal health

The endogenous molecular clock in skeletal muscle is necessary for maintenance of phenotype and function. Loss of Bmal1 solely from adult skeletal muscle (iMSBmal1−/−) results in reductions in specific tension, increased oxidative fibre type and increased muscle fibrosis with no change in feeding or activity. Disruption of the molecular clock in adult skeletal muscle is sufficient to induce changes in skeletal muscle similar to those seen in the Bmal1 knockout mouse (Bmal1−/−), a model of advanced ageing. iMSBmal1−/− mice develop increased bone calcification and decreased joint collagen, which in combination with the functional changes in skeletal muscle results in altered gait. This study uncovers a fundamental role for the skeletal muscle clock in musculoskeletal homeostasis with potential implications for ageing.

Enhancement of protein misfolding cyclic amplification by using concentrated cellular prion protein source

Protein misfolding cyclic amplification (PMCA) is a cell-free assay mimicking the prion replication process. However, constraints affecting PMCA have not been well-defined. Although cellular prion protein (PrP(C)) is required for prion replication, the influence of PrP(C) abundance on PMCA has not been assessed. Here, we show that PMCA was enhanced by using mouse brain material in which PrP(C) was overexpressed. Tg(MoPrP)4112 mice overexpressing PrP(C) supported more sensitive and efficient PMCA than wild type mice. As brain homogenate of Tg(MoPrP)4112 mice was diluted with PrP(C)-deficient brain material, PMCA became less robust. Our studies suggest that abundance of PrP(C) is a determinant that directs enhancement of PMCA. PMCA established here will contribute to optimizing conditions to enhance PrP(Sc) amplification by using concentrated PrP(C) source and expands the use of this methodology.

Enhancement of aging rat laryngeal muscles with endogenous growth factor treatment

Clinical evidence suggests that laryngeal muscle dysfunction is associated with human aging. Studies in animal models have reported morphological changes consistent with denervation in laryngeal muscles with age. Life‐long laryngeal muscle activity relies on cytoskeletal integrity and nerve–muscle communication at the neuromuscular junction (NMJ). It is thought that neurotrophins enhance neuromuscular transmission by increasing neurotransmitter release. We hypothesized that treatment with neurotrophin 4 (NTF4) would modify the morphology and functional innervation of aging rat laryngeal muscles. Fifty‐six Fischer 344xBrown Norway rats (6‐ and 30‐mo age groups) were used to evaluate to determine if NTF4, given systemically (n = 32) or directly (n = 24), would improve the morphology and functional innervation of aging rat thyroarytenoid muscles. Results demonstrate the ability of rat laryngeal muscles to remodel in response to neurotrophin application. Changes were demonstrated in fiber size, glycolytic capacity, mitochondrial, tyrosine kinase receptors (Trk), NMJ content, and denervation in aging rat thyroarytenoid muscles. This study suggests that growth factors may have therapeutic potential to ameliorate aging‐related laryngeal muscle dysfunction.