PRNP contains both intronic and upstream regulatory regions that may influence susceptibility to Creutzfeldt-Jakob Disease

The Prion protein (PrP) plays a central role in Creutzfeldt-Jakob Disease (CJD) and other transmissible spongiform encephalopathies (TSEs). Mutations in the protein coding region of the human PrP gene (PRNP), which have been proposed to alter the stability of the PrP protein, have been linked to a number of forms of TSE. However, the majority of CJD cases are not associated with mutations in the PRNP coding region and alternative mechanisms must therefore underlie susceptibility to these forms of CJD. Transgenic mice, that over- or under-express PrP genes, have shown a correlation between the level of PrP gene expression and the incubation time of disease. Polymorphisms that lead to alterations in human PRNP gene expression, could therefore be candidates for influencing susceptibility of an individual to CJD. In order to investigate this hypothesis, we have defined an upstream and intronic regulatory region of the PRNP gene. Sequencing of these regions in controls, sporadic CJD (sCJD) and variant CJD (vCJD) patients has identified three polymorphisms, all of which are more common in sCJD patients than controls. Our data suggests that polymorphisms in the regulatory region of the PRNP gene may be a risk factor for CJD.     

The role of PrP in health and disease

Transmissible spongiform encephalopathies (TSEs) such as scrapie in sheep, bovine spongiform encephalopathy (BSE) in cattle or Creutzfeldt-Jacob disease (CJD) and Gerstmann-Str?ussler-Scheinker syndrome (GSS) in humans, are caused by an infectious agent designated prion. The "protein only" hypothesis states that the prion consists partly or entirely of a conformational isoform of the normal host protein PrPc and that the abnormal conformer, when introduced into the organism, causes the conversion of PrPc into a likeness of itself. Since the proposal of the "protein only" hypothesis more than three decades ago, cloning of the PrP gene, studies on PrP knockout mice and on mice transgenic for mutant PrP genes allowed deep insights into prion biology. Reverse genetics on PrP knockout mice containing modified PrP transgenes was used to address a variety of problems: mapping PrP regions required for prion replication, studying PrP mutations affecting the species barrier, modeling familial forms of human prion disease, analysing the cell specificity of prion propagation and investigating the physiological role of PrP by structure-function studies. Many questions regarding the role of PrP in susceptibility to prions have been elucidated, however the physiological role of PrP and the pathological mechanisms of neurodegeneration in prion diseases are still elusive.     

Scrapie

Scrapie and other transmissible spongiform encephalopathies (TSEs) are characterized by similar pathology, biochemistry and genetics. The PrP protein and its conversion to the disease-related isoform, PrP^sc, are crucial for the development of all TSEs. Although scrapie is more often studied in laboratory rodents, it is not a natural disease of these animals, and much can be learned from the normal hosts, sheep. Disease incidence is linked to polymorphisms and mutations of the PrP gene. The complex relationships between PrP genotype and the survival of sheep subjected to scrapie infection are now being investigated in terms of the different structure of the PrP protein molecules produced by each allele. It is these structures and their differing abilities to convert to PrP^sc that hold the key to understanding why TSEs occur.     

The genetics of scrapie in sheep and goats

Scrapie, an invariably fatal disease of sheep and goats, is a transmissible spongiform encephalopathy (TSE). The putative infectious agent is the host-encoded prion protein, PrP. The development of scrapie is closely linked to polymorphisms in the host PrP gene. The pathogenesis of most TSEs involves conversion of normal, cellular PrP into a protease-resistant, pathogenic isoform called PrPSc. The conversion to PrPSc involves change in secondary structure; it is impacts on these structural changes that may link polymorphisms to disease. Within the structured C-terminal part of PrP polymorphisms have been reported at 15 and 10 codons of the sheep and goat PrP genes respectively. Three polymorphisms in sheep are acutely linked to the occurrence of scrapie: A136V, R154H and Q171R/H. These generate five commonly observed alleles: ARQ, ARR, AHQ, ARH and VRQ. ARR and AHQ are associated with resistance; ARQ, ARH and VRQ are associated with susceptibility. There are subtle effects of specific allele pairings (genotypes). Generally, more susceptible genotypes have younger ages at death from scrapie. Different strains of scrapie occur which may attack genotypes differently. Different sheep breeds vary in the assortment of the five alleles that they predominantly encode. The reason for this variation is not known. Furthermore, certain genotypes may be susceptible to scrapie in some breeds and resistant in others. The explanation is not known, but may relate to different scrapie strains circulating in different breeds, or there may be effects of other genes which modulate the effect of PrP.     

Comparative analysis of the prion protein (PrP) gene in cetacean species

The partial PrP gene sequence and the deduced protein of eight cetacean species, seven of which have never been reported so far, have been determined in order to extend knowledge of sequence variability of the PrP genes in different species and to aid in speculation on cetacean susceptibility to prions. Both the nucleotide and the deduced amino acid sequences have been analysed in comparison with some of the known mammalian PrPs. Cetacean PrPs present typical features of eutherian PrPs. The PrP gene from the species of the family Delphinidae gave identical nucleic acid sequences, while differences in the PrP gene were found in Balaenopteridae and Ziphidae. The phylogenetic tree resulting from analysis of the cetacean PrP gene sequences, together with reported sequences of some ungulates, carnivores and primates, showed that the PrP gene phylogenesis mirrors the species phylogenesis. The PrP gene of cetaceans is very close to species where natural forms of TSEs are known. From an analysis of the sequences and the phylogenesis of the PrP gene, susceptibility to or occurrence of prion diseases in cetaceans can not be excluded.     

Polymorphisms within the prion-like protein gene (Prnd) and their implications in human prion diseases, Alzheimer's disease and other neurological disorders

Only 10% of human transmissible spongiform encephalopathies (TSEs) are associated with mutations of the Prnp region encoding the prion protein (PrP). Recently, the murine PrP-like protein doppel (Dpl) was described and was shown to be overexpressed in certain strains of PrP knockout mice and to cause neurological diseases such as ataxia and Purkinje cell loss. To answer the question of whether there are any polymorphisms within the PrP-like protein gene (Prnd) that might cause or be involved in the development of TSEs, we investigated the complete open reading frame of the human Prnd gene from 58 patients who had died of genetic or sporadic Creutzfeldt-Jakob disease (CJD), Alzheimer's disease or other neurological disorders and from 111 controls. We found five new polymorphisms and one frame shift mutation. One silent polymorphism, which does not lead to an altered amino acid sequence, was also observed. Statistical analysis revealed a significant difference in the distribution of the Prnd genotype at codon 174 between sporadic CJD patients and healthy controls.     

Influence of amino acid substitutions related to inherited human prion diseases on the thermodynamic stability of the cellular prion protein

Transmissible spongiform encephalopathies (TSEs) are caused by a unique infectious agent which appears to be identical with PrPSc, an oligomeric, misfolded isoform of the cellular prion protein, PrPC. All inherited forms of human TSEs, i.e., familial Creutzfeldt-Jakob disease, Gerstmann-Str?ussler-Scheinker syndrome, and fatal familial insomnia, segregate with specific point mutations or insertions in the gene coding for human PrP. Here we have tested the hypothesis that these mutations destabilize PrPC and thus facilitate its conversion into PrPSc. Eight of the disease-specific amino acid replacements are located in the C-terminal domain of PrPC, PrP(121-231), which constitutes the only part of PrPC with a defined tertiary structure. Introduction of all these replacements into PrP(121-231) yielded variants with the same spectroscopic characteristics as wild-type PrP(121-231) and similar to full-length PrP(23-231), which excludes the possibility that the exchanges a priori induce a PrPSc-like conformation. The thermodynamic stabilities of the variants do not correlate with specific disease phenotypes. Five of the amino acid replacements destabilize PrP(121-231), but the other variants have the same stability as the wild-type protein. These data suggest that destabilization of PrPC is neither a general mechanism underlying the formation of PrPSc nor the basis of disease phenotypes in inherited human TSEs.     

绵羊PRNP遗传多样性与抗病育种研究进展

朊蛋白(Prion protein, PrP)是近年来被确认的引起人畜共患病的新型病原体, 也是目前证明的具有自我复制和传播能力的蛋白质。PrP在多种动物体内表达并具有重要生理作用, 其空间结构改变被认为是可传播性海绵状脑病(Transmissible spongiform encephalopathies, TSEs)的根源, 研究发现朊蛋白编码基因(PRNP)遗传多样性与绵羊对瘙痒病的抗病性具有显著相关性。文章主要介绍了绵羊PRNP遗传多样性与痒病抗病性的关系以及PRNP遗传多样性对繁殖力和其他主要生产性能的影响等方面的研究成果, 旨在为绵羊抗病育种研究提供理论参考。     

Differential expression of Prnp and Sprn in scrapie infected sheep also reveals Prnp genotype specific differences

The central role for PrP in the pathogenesis of the transmissible spongiform encephalopathies (TSEs) is illustrated by the resistance of Prnp^0/0 mice to disease and by the inverse association of Prnp gene dosage with incubation period. Understanding the role of PrP^C in TSEs necessitates knowledge of expression levels of the Prnp gene during the development of disease. SSBP/1 scrapie shows a defined pattern of disease progression and here we show that Prnp and shadow of PrP (Sprn) are differentially expressed in different brain areas and lymphoid tissues. Counter-intuitively we found that there is no positive correlation between expression of Prnp or Sprn and patterns of disease progression. Prnp and Sprn expression levels are both influenced by Prnp genotype; although the scrapie-sensitive VRQ/VRQ sheep did not express the highest level of either. In addition, infection with SSBP/1 scrapie seems to have little effect on either PrP or Shadoo expression levels.     

Three hamster species with different scrapie incubation times and neuropathological features encode distinct prion proteins.

Given the critical role of the prion protein (PrP) in the transmission and pathogenesis of experimental scrapie, we investigated the PrP gene and its protein products in three hamster species, Chinese (CHa), Armenian (AHa), and Syrian (SHa), each of which were found to have distinctive scrapie incubation times. Passaging studies demonstrated that the host species, and not the source of scrapie prions, determined the incubation time for each species, and histochemical studies of hamsters with clinical signs of scrapie revealed characteristic patterns of neuropathology. Northern (RNA) analysis showed the size of PrP mRNA from CHa, AHa, and SHa hamsters to be 2.5, 2.4, and 2.1 kilobases, respectively. Immunoblotting demonstrated that the PrP isoforms were of similar size (33 to 35 kilodaltons); however, the monoclonal antibody 13A5 raised against SHa PrP did not react with the CHa or AHa PrP molecules. Comparison of the three predicted amino acid sequences revealed that each is distinct. Furthermore, differences within the PrP open reading frame that uniquely distinguish the three hamster species are within a hydrophilic segment of 11 amino acids that includes polymorphisms linked to scrapie incubation times in inbred mice and an inherited prion disease of humans. Single polymorphisms in this region correlate with the presence or absence of amyloid plaques for a given hamster species or mouse inbred strain. Our findings demonstrate distinctive molecular, pathological, and clinical characteristics of scrapie in three related species and are consistent with the hypothesis that molecular properties of the host PrP play a pivotal role in determining the incubation time and neuropathological features of scrapie.     

PrP polymorphisms tightly control sheep prion replication in cultured cells

Prion diseases are fatal neurodegenerative disorders of animals and humans that are characterized by the conversion of the host-encoded prion protein (PrP) to an abnormal isoform. In several species, including humans, polymorphisms in the gene encoding the PrP protein tightly control susceptibility of individuals toward this disease. In the present study we show that Rov cells expressing an ovine PrP allele ((VRQ)PrP) associated with high susceptibility of sheep to scrapie were very sensitive to sheep prion transmission and replicated the agent to high titers. In contrast, we did not find any evidence of infection when Rov cells expressed similar levels of a PrP variant ((ARR)PrP) linked to resistance. Our data provide the first direct evidence that natural PrP polymorphisms may affect prion susceptibility by controlling prion replication at the cell level. The study of how PrP polymorphisms influence the genetic control of prion propagation in cultured Rov cells may help elucidate basic mechanisms of prion replication.     

Insights into prion strains and neurotoxicity

Transmissible spongiform encephalopathies (TSEs) are neurodegenerative diseases that are caused by prions and affect humans and many animal species. It is now widely accepted that the infectious agent that causes TSEs is PrP(Sc), an aggregated moiety of the host-derived membrane glycolipoprotein PrP(C). Although PrP(C) is encoded by the host genome, prions themselves encipher many phenotypic TSE variants, known as prion strains. Prion strains are TSE isolates that, after inoculation into distinct hosts, cause disease with consistent characteristics, such as incubation period, distinct patterns of PrP(Sc) distribution and spongiosis and relative severity of the spongiform changes in the brain. The existence of such strains poses a fascinating challenge to prion research.     

The role of genetics in chronic wasting disease of North American cervids

Chronic wasting disease (CWD) is a major concern for the management of North American cervid populations. This fatal prion disease has led to declines in populations which have high CWD prevalence and areas with both high and low infection rates have experienced economic losses in wildlife recreation and fears of potential spill-over into livestock or humans. Research from human and veterinary medicine has established that the prion protein gene (Prnp) encodes the protein responsible for transmissible spongiform encephalopathies (TSEs). Polymorphisms in the Prnp gene can lead to different prion forms that moderate individual susceptibility to and progression of TSE infection. Prnp genes have been sequenced in a number of cervid species including those currently infected by CWD (elk, mule deer, white-tailed deer, moose) and those for which susceptibility is not yet determined (caribou, fallow deer, sika deer). Over thousands of sequences examined, the Prnp gene is remarkably conserved within the family Cervidae; only 16 amino acid polymorphisms have been reported within the 256 amino acid open reading frame in the third exon of the Prnp gene. Some of these polymorphisms have been associated with lower rates of CWD infection and slower progression of clinical CWD. Here we review the body of research on Prnp genetics of North American cervids. Specifically, we focus on known polymorphisms in the Prnp gene, observed genotypic differences in CWD infection rates and clinical progression, mechanisms for genetic TSE resistance related to both the cervid host and the prion agent and potential for natural selection for CWD-resistance. We also identify gaps in our knowledge that require future research.     

Successful transmission of three mouse-adapted scrapie strains to murine neuroblastoma cell lines overexpressing wild-type mouse prion protein

Propagation of the agents responsible for transmissible spongiform encephalopathies (TSEs) in cultured cells has been achieved for only a few cell lines. To establish efficient and versatile models for transmission, we developed neuroblastoma cell lines overexpressing type A mouse prion protein, MoPrP(C)-A, and then tested the susceptibility of the cells to several different mouse-adapted scrapie strains. The transfected cell clones expressed up to sixfold-higher levels of PrP(C) than the untransfected cells. Even after 30 passages, we were able to detect an abnormal proteinase K-resistant form of prion protein, PrP(Sc), in the agent-inoculated PrP-overexpressing cells, while no PrP(Sc) was detectable in the untransfected cells after 3 passages. Production of PrP(Sc) in these cells was also higher and more stable than that seen in scrapie-infected neuroblastoma cells (ScN2a). The transfected cells were susceptible to PrP(Sc)-A strains Chandler, 139A, and 22L but not to PrP(Sc)-B strains 87V and 22A. We further demonstrate the successful transmission of PrP(Sc) from infected cells to other uninfected cells. Our results corroborate the hypothesis that the successful transmission of agents ex vivo depends on both expression levels of host PrP(C) and the sequence of PrP(Sc). This new ex vivo transmission model will facilitate research into the mechanism of host-agent interactions, such as the species barrier and strain diversity, and provides a basis for the development of highly susceptible cell lines that could be used in diagnostic and therapeutic approaches to the TSEs.     

Quantitative profiling of the pathological prion protein allotypes in bank voles by liquid chromatography-mass spectrometry

The conversion of the cellular prion protein (PrP(C)) into a misfolded isoform (PrP(TSE)) that accumulates in the brain of affected individuals is the key feature of transmissible spongiform encephalopaties (TSEs). Susceptibility to TSEs is influenced by polymorphisms of the prion gene suggesting that the presence of certain amino acid residues may facilitate the pathological conversion. In this work, we describe a quantitative, fast and reliable HPLC-MS method that allowed to demonstrate that in the brain of 109(Met/Ile) heterozygous bank voles infected with the mouse adapted scrapie strain 139A, there are comparable amounts of PrP(TSE) with methionine or isoleucine in position 109, suggesting that in this TSE model the two allotypes have similar rates of accumulation. This method can be easily adapted for the quantitative determination of PrP allotypes in the brain of other natural or experimental TSE models.     

Scrapie infection of prion protein-deficient cell line upon ectopic expression of mutant prion proteins

Expression of the cellular prion protein (PrP(C)) is crucial for susceptibility to prions. In vivo, ectopic expression of PrP(C) restores susceptibility to prions and transgenic mice that express heterologous PrP on a PrP knock-out background have been used extensively to study the role of PrP alterations for prion transmission and species barriers. Here we report that prion protein knock-out cells can be rendered permissive to scrapie infection by the ectopic expression of PrP. The system was used to study the influence of sheep PrP-specific residues in mouse PrP on the infection process with mouse adapted scrapie. These studies reveal several critical residues previously not associated with species barriers and demonstrate that amino acid residue alterations at positions known to have an impact on the susceptibility of sheep to sheep scrapie also drastically influence PrP(Sc) formation by mouse-adapted scrapie strain 22L. Furthermore, our data suggest that amino acid polymorphisms located on the outer surfaces of helix 2 and 3 drastically impact conversion efficiency. In conclusion, this system allows for the fast generation of mutant PrP(Sc) that is entirely composed of transgenic PrP and is, thus, ideally suited for testing if artificial PrP molecules can affect prion replication. Transmission of infectivity generated in HpL3-4 cells expressing altered PrP molecules to mice could also help to unravel the potential influence of mutant PrP(Sc) on host cell tropism and strain characteristics in vivo.     

Human genetic susceptibility to infectious disease

Recent genome-wide studies have reported novel associations between common polymorphisms and susceptibility to many major infectious diseases in humans. In parallel, an increasing number of rare mutations underlying susceptibility to specific phenotypes of infectious disease have been described. Together, these developments have highlighted a key role for host genetic variation in determining the susceptibility to infectious disease. They have also provided insights into the genetic architecture of infectious disease susceptibility and identified immune molecules and pathways that are directly relevant to the human host defence.     

Frequencies of PrP gene haplotypes in British sheep flocks and the implications for breeding programmes

AIMS: To analyse the frequencies of prion (PrP) gene haplotypes in UK sheep flocks and evaluate their relevance to transmissible spongiform encephalopathies (TSEs) and TSE resistance breeding programmes in sheep. METHODS AND RESULTS: Genomic DNA isolated from sheep blood was PCR amplified for the coding region of the PrP gene and then sequenced. This study has analysed the sequence of PrP between codons 110 and 245 in 6287 ARQ haplotypes revealing a total of eight variant sequences, which represent a higher than expected 41% of all ARQ haplotypes. The additional PrP gene dimorphisms were M112T, L141F, M137T, H143R, H151C, P168L, Q175E and P241S. CONCLUSION: The results do not suggest a correlation between the occurrence of a specific ARQ haplotype and the scrapie disease status of a flock. The ARQ haplotype variability appears to be different in the UK sheep flocks compared with sheep flocks from outside the UK. SIGNIFICANCE AND IMPACT OF THE STUDY: Additional PrP dimorphisms may impact on the methodologies used for standard PrP genotyping in sheep breeding programmes. Some of these polymorphisms were found with significant frequencies in the UK sheep flocks and should therefore be considered in breeding programmes.     

How independent are TSE agents from their hosts?

Central to understanding the nature TSE agents (or prions) is how their genetic information is distinguished from the host. Are TSEs truly infectious diseases with host-independent genomes, or are they aberrations of a host component derived from the host genome? Recent experiments tested whether glycosylation of host PrP affects TSE strain characteristics. Wild-type mice were infected with 3 TSE strains passaged through transgenic mice with PrP devoid of glycans at 1 or both N-glycosylation sites. Strain-specific characteristics of 1 TSE strain changed but did not change for 2 others. Changes resulted from the selection of mutant TSE strains in a novel replicative environment. In general the properties of established TSEs support the genetic independence of TSE agents from the host, and specifically the primary structure of PrP does not directly encode TSE agent properties. However sporadic TSEs, challenge this independency. The prion hypothesis explains emerging TSEs relatively successfully but poorly accounts for the diversity and mutability of established TSE strains, or how many different infectious conformations are sustained thermodynamically. Research on early changes in RNA expression and events at the ribosome may inform the debate on TSE agent properties and their interaction with host cell machinery.     

Follicular dendritic cell dedifferentiation by treatment with an inhibitor of the lymphotoxin pathway dramatically reduces scrapie susceptibility

Transmissible spongiform encephalopathies (TSEs) may be acquired peripherally, in which case infectivity usually accumulates in lymphoid tissues before dissemination to the nervous system. Studies of mouse scrapie models have shown that mature follicular dendritic cells (FDCs), expressing the host prion protein (PrP(c)), are critical for replication of infection in lymphoid tissues and subsequent neuroinvasion. Since FDCs require lymphotoxin signals from B lymphocytes to maintain their differentiated state, blockade of this stimulation with a lymphotoxin beta receptor-immunoglobulin fusion protein (LT beta R-Ig) leads to their temporary dedifferentiation. Here, a single treatment with LT beta R-Ig before intraperitoneal scrapie inoculation blocked the early accumulation of infectivity and disease-specific PrP (PrP(Sc)) within the spleen and substantially reduced disease susceptibility. These effects coincided with an absence of FDCs in the spleen for ca. 28 days after treatment. Although the period of FDC dedifferentiation was extended to at least 49 days by consecutive LT beta R-Ig treatments, this had little added protective benefit after injection with a moderate dose of scrapie. We also demonstrate that mature FDCs are critical for the transmission of scrapie from the gastrointestinal tract. Treatment with LT beta R-Ig before oral scrapie inoculation blocked PrP(Sc) accumulation in Peyer's patches and mesenteric lymph nodes and prevented neuroinvasion. However, treatment 14 days after oral inoculation did not affect survival time or susceptibility, suggesting that infectivity may have already spread to the peripheral nervous system. Although manipulation of FDCs may offer a potential approach for early intervention in peripherally acquired TSEs, these data suggest that the duration of the treatment window may vary widely depending on the route of exposure.