Browsing by Person "Baybutt, Herbert"

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Host PrP Glycosylation: A Major Factor Determining the Outcome of Prion Infection
(Public Library of Science, 2008-04-15) Tuzi, Nadia L.; Cancellotti, Enrico; Baybutt, Herbert; Blackford, Lorraine; Bradford, Barry; Pinston, Chris; Coghill, Anne; Hart, Patricia; Piccardo, Pedro; Barron, Rona; Manson, Jean C.
The expression of the prion protein (PrP) is essential for transmissible spongiform encephalopathy (TSE) or prion diseases to occur, but the underlying mechanism of infection remains unresolved. To address the hypothesis that glycosylation of host PrP is a major factor influencing TSE infection, we have inoculated gene-targeted transgenic mice that have restricted N-linked glycosylation of PrP with three TSE strains. We have uniquely demonstrated that mice expressing only unglycosylated PrP can sustain a TSE infection, despite altered cellular location of the host PrP. Moreover we have shown that brain material from mice infected with TSE that have only unglycosylated PrPSc is capable of transmitting infection to wild-type mice, demonstrating that glycosylation of PrP is not essential for establishing infection within a host or for transmitting TSE infectivity to a new host. We have further dissected the requirement of each glycosylation site and have shown that different TSE strains have dramatically different requirements for each of the glycosylation sites of host PrP, and moreover, we have shown that the host PrP has a major role in determining the glycosylation state of de novo generated PrPSc.
How does host PrP control TSE disease?
(Springer, 2004-05) Manson, Jean; Barron, Rona; Tuzi, Nadia L.; Baybutt, Herbert; Bishop, Matthew; Cancellotti, Enrico; Hart, Patricia; Jamieson, L.; Aitchison, L.; Gall, E.; Bradford, Barry; King, Declan
PrP is central to the TSE disease process and has been hypothesised to be the infectious agent. Polymorphisms in the PrP gene of a number of species are associated with different incubation times of disease following exposure to an infectious agent and mutations in the human PrP gene can apparently lead to spontaneous genetic disease. Strains of TSE agent are proposed to be generated and maintained through differences in glycosylation or conformation of PrP and the barrier to infection between species is thought to be due to the differences in the sequence of PrP between different species. In order to test these hypotheses, we have introduced specific modifications into the endogenous mouse Prnp gene by gene targeting. The mutated PrP gene is in the correct location under the control of the endogenous Prnp regulatory sequences and thus expressed in the same tissues and amounts as the wild type Prnp gene. This strategy therefore allows the effect of specific mutations in the PrP gene to be assessed. We have introduced mutations into the Prnp gene which prevent glycosylation at each or both of the two N-linked glycosylation sites of PrP and are using TSE infection of these mice to investigate the role of PrP glycosylation in strain targeting and strain determination. We have investigated the role of the sequence of the host PrP gene in determining susceptibility by inserting point mutations or replacing the murine PrP gene with that of human or bovine PrP. This has produced a model of TSE disease which contains high levels of infectivity in the absence of PrPSc and we are using this model to determine the nature of the infectious agent. We have thus established that the gene targeting approach can produce models for TSE disease which address fundamental questions associated with these diseases. We aim to use these models to address central issues including the origin of strains, the species barrier and the nature of the infectious agent.
Polymorphisms at codons 108 and 189 in murine PrP play distinct roles in the control of scrapie incubation time
(Microbiology Society, 2005-03-01) Barron, Rona; Baybutt, Herbert; Tuzi, Nadia L.; McCormack, James; King, Declan; Moore, Richard C.; Melton, David W.; Manson, Jean C.
Susceptibility to transmissible spongiform encephalopathies (TSEs) is associated strongly with PrP polymorphisms in humans, sheep and rodents. In mice, scrapie incubation time is controlled by polymorphisms at PrP codons 108 (leucine or phenylalanine) and 189 (threonine or valine), but the precise role of each polymorphism in the control of disease is unknown. The L108F and T189V polymorphisms are present in distinct structural regions of PrP and thus provide an excellent model with which to investigate the role of PrP structure and gene variation in TSEs. Two unique lines of transgenic mice, in which 108F and 189V have been targeted separately into the endogenous murine Prnp a gene, have been produced. TSE inoculation of inbred lines of mice expressing all allelic combinations at codons 108 and 189 has revealed a complex relationship between PrP allele and incubation time. It has been established that both codons 108 and 189 control TSE incubation time, and that each polymorphism plays a distinct role in the disease process. Comparison of ME7 incubation times in mouse lines that are heterozygous at both codons has also identified a previously unrecognized intramolecular interaction between PrP codons 108 and 189.
A single amino acid alteration (101L) introduced into murine PrP dramatically alters incubation time of transmissible spongiform encephalopathy
(EMBO Press, 1999-12-01) Manson, Jean C.; Jamieson, Elizabeth; Baybutt, Herbert; Tuzi, Nadia L.; Barron, Rona; McConnell, Irene; Somerville, Robert; Ironside, James; Will, Robert; Sy, Man-Sun; Melton, David W.; Hope, James; Bostock, Christopher
A mutation equivalent to P102L in the human PrP gene, associated with Gerstmann–Straussler syndrome (GSS), has been introduced into the murine PrP gene by gene targeting. Mice homozygous for this mutation (101LL) showed no spontaneous transmissible spongiform encephalopathy (TSE) disease, but had incubation times dramatically different from wild-type mice following inoculation with different TSE sources. Inoculation with GSS produced disease in 101LL mice in 288 days. Disease was transmitted from these mice to both wild-type (226 days) and 101LL mice (148 days). In contrast, 101LL mice infected with ME7 had prolonged incubation times (338 days) compared with wild-type mice (161 days). The 101L mutation does not, therefore, produce any spontaneous genetic disease in mice but significantly alters the incubation time of TSE infection. Additionally, a rapid TSE transmission was demonstrated despite extremely low levels of disease-associated PrP.
A single amino acid alteration in murine PrP dramatically alters the TSE incubation time
(Springer, 2000) Manson, Jean; Barron, Rona; Jamieson, Elizabeth; Baybutt, Herbert; Tuzi, Nadia L.; McConnell, I.; Melton, David W.; Hope, J.; Bostock, C.
In order to investigate mutations linked to human TSEs, we have used the technique of gene targeting to introduce specific mutations into the endogenous murine PrP gene which resulted in a P101L substitution (Prnp a101L) in the murine PrP gene. This mutation is equivalent to the 102L mutation in the human PrP gene which is associated with Gerstmann-Sträussler syndrome. Since the mutated gene is in the correct chromosomal location and control of the mutant gene expression is identical to that of the wild type murine PrP gene, the precise effect of the 101L mutation in the uninfected and TSE infected mouse can be investigated in this transgenic model. Mice homozygous for this mutation (101LL) while showing no spontaneous TSE disease were more susceptible to TSE disease than wild type mice following inoculation with GSS infectivity. Disease was transmitted from these mice to mice both with and without the Prnp a101L allele. The 101L mutation does not therefore produce spontaneous genetic disease in mice but does dramatically alter incubation periods following TSE infection. Additionally, a rapid TSE transmission was demonstrated associated with extremely low amounts of PrPSc.