Dallas Foster

Transgenetic studies implicate interactions between homologous PrP isoforms in scrapie prion replication.

Transgenic (Tg) mice expressing both Syrian hamster (Ha) and mouse (Mo) prion protein (PrP) genes were used to probe the mechanism of scrapie prion replication. Four Tg lines expressing HaPrP exhibited distinct incubation times ranging from 48 to 277 days, which correlated inversely with HaPrP mRNA and HaPrPC. Bioassays of Tg brain extracts showed that the prion inoculum dictates which prions are synthesized de novo. Tg mice inoculated with Ha prions had approximately 10(9) ID50 units of Ha prions per gram of brain and less than 10 units of Mo prions. Conversely, Tg mice inoculated with Mo prions synthesized Mo prions but not Ha prions. Similarly, Tg mice inoculated with Ha prions exhibited neuropathologic changes characteristic of hamsters with scrapie, while Mo prions produced changes similar to those in non-Tg mice. Our results argue that species specificity of scrapie prions resides in the PrP sequence and prion synthesis is initiated by a species-specific interaction between PrPSc in the inoculum and homologous PrPC.

Transgenic mice expressing hamster prion protein produce species-specific scrapie infectivity and amyloid plaques

Three transgenic mouse lines designated Tg 69, 71, and 81 were produced harboring a Syrian hamster (Ha) prion protein (PrP) gene; all expressed the cellular HaPrP isoform in their brains. Inoculation of Tg 81 mice or hamsters with Ha prions caused scrapie in integral of 75 days; nontransgenic control mice failed to develop scrapie after greater than 500 days. Tg 71 mice inoculated with Ha prions developed scrapie in integral of 170 days. Both Tg 71 and Tg 81 mice exhibited spongiform degeneration and reactive astrocytic gliosis, and they produced the scrapie HaPrP isoform in their brains. Tg 81 brains also showed HaPrP amyloid plaques characteristic of Ha scrapie and contained integral of 10(9) ID50 units of Ha prions based on Ha bioassays. Our findings argue that the PrP gene modulates scrapie susceptibility, incubation times, and neuropathology; furthermore, they demonstrate synthesis of infectious scrapie prions programmed by a recombinant DNA molecule.

Spontaneous neurodegeneration in transgenic mice with mutant prion protein.

Transgenic mice were created to assess genetic linkage between Gerstmann-Straussler-Scheinker syndrome and a leucine substitution at codon 102 of the human prion protein gene. Spontaneous neurologic disease with spongiform degeneration and gliosis similar to that in mouse scrapie developed at a mean age of 166 days in 35 mice expressing mouse prion protein with the leucine substitution. Thus, many of the clinical and pathological features of Gerstmann-Straussler-Scheinker syndrome are reproduced in transgenic mice containing a prion protein with a single amino acid substitution, illustrating that a neurodegenerative process similar to a human disease can be genetically modeled in animals.

Degeneration of skeletal muscle, peripheral nerves, and the central nervous system in transgenic mice overexpressing wild-type prion proteins

Prion diseases of humans and animals are known to be caused by infection with prions containing PrPSc or mutation of the prion protein (PrP) gene. During transgenetic studies, we discovered that uninoculated older mice harboring high copy numbers of wild-type (wt) PrP transgenes derived from Syrian hamsters (SHa), sheep (She), and PrP-B mice developed truncal ataxia, hindlimb paralysis, and tremors. These transgenic (Tg) mice exhibited a profound necrotizing myopathy involving skeletal muscle, a demyelinating polyneuropathy, and focal vacuolation of the central nervous system. Development of disease was dependent on transgene dosage. For example, half of all Tg(SHaPrP+/+)7 mice homozygous for the SHaPrP transgene array developed disease by approximately 460 days of age, while no hemizygous Tg(SHaPrP+/o)7 mice became ill before 650 days. The novel neurologic syndrome found in older Tg(wtPrP) mice implies that overexpression of wtPrPC is pathogenic and widens the spectrum of prion diseases.

Propagation of prions with artificial properties in transgenic mice expressing chimeric PrP genes

Transgenic mice expressing chimeric prion protein (PrP) genes derived from Syrian hamster (SHa) and mouse (Mo) PrP genes were constructed. One SHa/MoPrP gene, designated MH2M PrP, contains five amino acid substitutions encoded by SHaPrP, while another construct, designated MHM2 PrP, has two substitutions. Transgenic (Tg) (MH2M PrP) mice were susceptible to both Syrian hamster and mouse prions, whereas three lines expressing MHM2 PrP were resistant to Syrian hamster prions. The brains of Tg(MH2M PrP) mice dying of scrapie contained chimeric PrPSc and prions with an artificial host range favoring propagation in mice that express the corresponding chimeric PrP and were also transmissible, at reduced efficiency, to nontransgenic mice and hamsters. Our findings provide genetic evidence for homophilic interactions between PrPSc in the inoculum and PrPc synthesized by the host.

Paradoxical shortening of scrapie incubation times by expression of prion protein transgenes derived from long incubation period mice.

Prolonged incubation times for experimental scrapie in I/LnJ mice are dictated by a dominant gene linked to the prion protein gene (Prn-p). Transgenic mice were analyzed to discriminate between an effect of the I/LnJ Prn-pb allele and a distinct incubation time locus designated Prn-i. Paradoxically, 4 independent Prn-pb transgenic mouse lines had scrapie incubation times shorter than nontransgenic controls, instead of the anticipated prolonged incubation periods. Aberrant or overexpression of the Prn-pb transgenes may dictate abbreviated incubation times, masking genuine Prn-p/Prn-i congruence; alternatively, a discrete Prn-i gene lies adjacent to Prn-p.

Spontaneous neurodegeneration in transgenic mice with prion protein codon 101 proline----leucine substitution.

Gerstmann-Sträussler-Scheinker syndrome (GSS) is an autosomal, dominantly inherited, human neurodegenerative disease that can sometimes be transmitted to non-human primates and rodents through intracerebral inoculation of brain homogenates from patients. Recent studies of GSS demonstrated significant genetic linkage between GSS and a leucine substitution at codon 102 of the human prion protein (PrP) gene. Transgenic mice were created to test the biologic activity of this mutation. Spontaneous neurologic disease with spongiform degeneration developed in one of three lines of transgenic mice containing murine PrP genes with a leucine substitution at codon 101 (homologous to codon 102 in humans). Transmission studies of brain homogenates from affected mice are in progress. These results indicate that some of the clinical and pathologic features of GSS can be reproduced in a transgenic mouse paradigm; this represents the first time a dominantly inherited, neurodegenerative process similar to a human disease has been genetically modeled in an experimental animal (Hsiao and Prusiner 1990).