The prion protein in normal cells and disease : studies on the cellular processing of bovine PrPC and molecular characterization of the Nor98 prion /

Klingeborn, Mikael,

January 2006

Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2006. / Härtill 3 uppsatser.

Defining mechanisms of neurodegeneration associated with protein misfolding diseases

Lane, Fiona Mary

January 2015

Protein misfolding diseases (PMDs) are a broad group of disorders including Alzheimer’s, Parkinson’s and prion diseases. They are characterised by the presence of aggregated, misfolded host proteins which are thought to cause cell death. Prion diseases are associated with misfolded prion protein (PrPSc), which has a tendency to form fibrillar aggregates. By contrast, Alzheimer’s disease (AD) is associated with misfolded amyloid beta (Aβ), which aggregates to form characteristic Aβ plaques. A feature which is common across PMDs is that small assemblies (oligomers) of the misfolded proteins are thought to be the important neurotoxic species, and it has been proposed that there may be a shared mechanism leading to cell death across PMDs caused by oligomers. In this study, the toxicity of different misfolded forms of recombinant PrP (recPrP) and recombinant Aβ (recAβ) and the mechanisms leading to cell death were investigated using a primary cell culture model. In addition, the importance of the disulphide bond in recPrP in relation to oligomer formation was explored using size exclusion chromatography and mass spectrometry, the toxicity of the different resulting oligomer populations were also investigated. Both recPrP oligomers and fibrils were shown to cause toxicity to mouse primary cortical neurons. Interestingly, oligomers were shown to cause apoptotic cell death, while the fibrils did not, suggesting the activation of different pathways. By contrast, recAβ fibrils were shown to be non-toxic to cortical neurons, Aβ oligomers, however, were shown to cause toxicity. Similar to recPrP, my data showed that it is likely that recAβ 1-42 oligomers also cause apoptosis. However, by contrast this seemed to be caused by excitotoxicity, which was not found to be the case for recPrP. Additionally, I have shown that the presence or absence of the disulphide bond in PrP has a profound effect on the size of oligomers which form. RecPrP lacking a disulphide bond leads to the formation of larger oligomers which are highly toxic to primary neurons. Findings from this study suggest that structural properties such as the disulphide bond in PrP can affect the size and toxicity of oligomers, furthermore, whilst oligomers have been shown to be important in both AD and prion diseases, they may not trigger the same pathways leading to cell death.

616.8

PrP catabolites as determinants of TSE susceptibility

Love, Charmaine

January 2011

Transmissible spongiform encephalopathies (TSEs) are a group of fatal neurodegenerative diseases that are characterised by long incubation periods, protein aggregation and vacuolation. During TSE pathogenesis the normal, cellular prion protein, (PrPC), which is encoded by the gene PRNP, misfolds and accumulates as abnormal disease associated prion protein, (PrPSc) within the central nervous system. Variants of the Prion protein gene are associated with susceptibility to TSE disease. For example sheep scrapie disease is modulated by several PRNP alleles, with certain alleles carried by susceptible animals being different from those carried by resistant animals. The mechanisms linking PRNP genetics and disease is poorly understood but may involve protein sequence, PrPC expression levels, and possibly differences in protein processing. Post-translational modification of PrPC leads to specific cleavage (alpha cleavage) between amino acids 115/116 of ovine PrP, producing two fragments C1 and N1. Cleavage of PrP may occur as a protective mechanism, as a response to changes in the cellular environment or as a feature of an as yet unknown biological function. In the context of TSEs, alpha cleavage may inadvertently provide a protective role by reducing available PrPC protein for conversion into PrPSc, assuming that the C1 fragment would be an inefficient substrate for conversion, the opposite theory was also proposed. The former hypothesis became the focus of this present study, with the idea that total full-length PrPC, total C1 or the ratio between full-length PrPC and C1 may be linked to differences in scrapie susceptibility. To investigate these aims the C1 fragment was measured as a percentage of total PrPC in different PRNP genotypes with varying degrees of susceptibility to scrapie and in different brain regions. This study found that PrPC alpha cleavage increased during development from the new born lamb to the adult sheep, which may have consequences for the susceptibility differences related to age. There are also variations in the amount of alpha cleavage between brain regions such as cortex and medulla that may influence scrapie strain targeting. Overall the amount of the C1 fragment in the different brain areas varied as much as 10x (range 5% to 60%). There was a significant difference in the ratio of C1 to the other PrPC forms between two PRNP genotype groups carrying the VRQ and ARQ allele but there was no correlation between C1 level and scrapie susceptibility or scrapie incubation period in our scrapie models. Alpha cleavage of PrPC also occurs in various transgenic mouse models expressing different ruminant PrP sequences. In PrPC over-expressing transgenic mouse models a higher ratio of C1 was observed, this may suggest a link between PrPC expression levels and alpha cleavage. Transgenic mice are therefore important models to further investigate the link between PrPC biology and scrapie disease phenotype. In conclusion, this thesis has shown for the first time that certain ovine PRNP alleles can influence alpha cleavage of the PrPC protein; however it appears not to be a significant indicator of TSE disease susceptibility in sheep.

636.089

Effect of congruent gastro-intestinal pathogen infection on oral prion disease susceptibility

Sánchez Quintero, Alejandra

January 2018

Transmissible spongiform encephalopathies (TSEs) or prion diseases, are subacute neurodegenerative diseases that infect humans and animals. Many of these diseases are acquired by peripheral exposure (e.g. orally). After oral exposure prion replication within the Peyer's patches (PP) in the small intestine is necessary for the efficient spread of the disease to the brain. Within the intestine, bacteria and pathogenic microorganisms can affect the status of the gut associated lymphoid tissue (GALT). GALT consists of PP and isolated lymphoid follicles (ILF) that maintain homeostasis and protect from infections. Therefore, factors which modify GALT status, might dramatically affect oral prion disease pathogenesis by influencing the uptake of prions from the gut lumen or expanding their distribution within the host. Chronic intestinal helminth infections are common in animals and in man, and can cause significant pathology within the intestine. Little is known of the effects that intestinal helminth infections may have on oral prion diseases susceptibility. Therefore, in this study the influence that co-infection with Heligmosomoides polygyrus (a natural pathogen of the mouse small intestine) may have on oral prion disease pathogenesis and susceptibility was determined. The studies consisted of groups of 4 (for H. polygyrus characterization and for early prion detection) and 8 (for H. polygyrus-prion co-infection to terminal stage) mice infected with H. polygyrus (orally) alone or subsequently infected with ME7 scrapie prions (orally) at different time-points after parasitic infection. The effects of the H. polygyrus infection alone, and on oral prion disease pathogenesis and susceptibility were then determined. Initially the characterization of H. polygyrus infection on the host intestine revealed that this parasite caused significant pathology in the small intestine and affected the GALT microarchitecture. In the PP follicles, H. polygyrus infection increased the area of follicular dendritic cell expression, altered the positioning of mononuclear phagocytes and increased M cell density. H. polygyrus infection also reduced the number of ILF in both the small and large intestines. Additional studies in mice co-infected with a low dose of prions, revealed that these pathological changes affected the survival time and disease susceptibility. Data also show that the extent of the effects on prion disease pathogenesis and susceptibility were dependent on the stage of the helminth infection at which the mice were orally-exposed to prions. Data demonstrate that co-infection with the gastrointestinal helminth H. polygyrus can influence oral prion disease pathogenesis and susceptibility. Helminth infections can significantly modify the microarchitecture of the gut and the GALT. Data presented suggest the pathological changes that pathogens such as small intestinal helminths cause, may also influence the uptake of prions from the gut lumen after oral exposure.

Prion Protein Gene and Its Shadow

Premzl, Marko, Marko.Premzl@anu.edu.au, premzl@excite.com

January 2004

Prion protein (PrP) is best known for its involvement in prion diseases. A normal, dynamic isoform of prion protein (PrP^C) transforms into a pathogenic, compact isoform (PrP^Sc) during prion disease pathogenesis. The PrP^Sc, acting as a template upon which PrP^C molecules are refolded into a likeness of itself, accumulates in the brain neurones and causes disease. It is the only known component of prions, proteinaceous infectious particles. Both prion protein isoforms have the same primary amino acid structure and are encoded by the same prion protein gene (PRNP). PRNP determines susceptibility/disposition to prion diseases and their phenotypes.¶The normal function of PRNP is elusive. The Prnp knock-out mice with disrupted ORF show only very subtle phenotype. A number of hypotheses were proposed on the function of mammalian PRNP. The extracellular, GPI-anchored, glycosylated mammalian PrP^C expressed in a heterogenous set of cells could: transport copper from extracellular to intracellular milieu, buffer copper from synapse, contribute to redox signalling, act neuroprotectively, mediate cell-cell contacts, affect lymphocyte activation, participate in nucleic acid metabolism, be a memory molecule, and be a signal-transduction protein.¶ Experimental evidence demonstrated a redundancy between the PRNP and another, unknown gene. The critical issue therefore is to discover new genes homologous with PRNP, candidates for this redundancy. Using unpublished data, a sequence of zebrafish cDNA sequenced by Prof. Tatjana Simonic’s group (University of Milan, Italy), I discovered a new paralogue of PRNP. By searching manually, and in a targeted fashion, data deposited in public biological databases, I compiled support for the new human gene Shadow of prion protein (SPRN) including the direct evidence, homology-based evidence and ab initio gene prediction. The protein product called Shadoo (shadow in Japanese) is an extracellular, potentially glycosylated and GPI-anchored protein of a mature size of 100-odd amino acids. It is conserved from fish (zebrafish, Fugu, Tetraodon) to mammals (human, mouse, rat), and exhibits similarity of overall protein features with PrP. Most remarkably, the Sho is the first human/mammalian protein apart from PrP that contains the middle hydrophobic region that is essential for both normal and pathogenic properties of PrP. As this region is critical for heterodimerization of PrP, Sho may have potential to interact with PrP and is a likely candidate for the Protein X. Mammalian SPRN could be predominantly expressed in brain (Tatjana Simonic Lab, University of Milan, Italy).¶ Using the same approach to search public databases, I found, in addition, a fish duplicate of SPRN called SPRNB, and defined a new vertebrate SPRN gene family. Further, I also expanded a number of known fish genes from the PRNP gene family. The total number of the new genes that I discovered is 11. With the representatives of two vertebrate gene family datasets in hand, I conducted comparative genomic analysis in order to determine evolutionary trajectories of the SPRN and PRNP genes. This analysis, complemented with phylogenetic studies (Dr. Lars Jermiin, University of Sydney, Australia), demonstrated conservative evolution of the mammalian SPRN gene, and more relaxed evolutionary constraints acting on the mammalian PRNP gene. This evolutionary dialectic challenges widely adopted view on the “highly conserved vertebrate” PRNP and indicates that the SPRN gene may have more prominent function. More conserved Sprn could therefore substitute for the loss of less conserved, dispensable Prnp in the Prnp knock-out mice. Furthermore, the pathogenic potential of PRNP may be a consequence of relaxed evolutionary constraints.¶ Depth of comparative genomic analysis, strategy to understand biological function, depends on the number of species in comparison and their relative evolutionary distance. To understand better evolution and function of mammalian PRNP, I isolated and characterized the PRNP gene from Australian model marsupial tammar wallaby (Macropus eugenii). Marsupials are mammals separated from their eutherian relatives by roughly 180 million years. Comparison of the tammar wallaby and Brazilian opossum PrP with other vertebrate PrPs indicated patterns of evolution of the PrP regions. Whereas the repeat region is conserved within lineages but differs between lineages, the hydrophobic region is invariably conserved in all the PrPs. Conservation of PrP between marsupials and eutherians suggests that marsupial PrP could have the same pathogenic potential as eutherian PrPs. Using the marsupial PRNP gene in comparison with the PRNP genes from eutherian species in which prion diseases occur naturally (human, bovine, ovine) or experimentally (mouse), I defined gene regions that are conserved mammalian-wide and showed the utility of the marsupial genomic sequence for cross-species comparisons. These regions are potential regulatory elements that could govern gene expression and posttranscriptional control of mRNA activity. These findings shed new light on the normal function of mammalian PRNP supporting best the signal-transduction hypothesis. The normal function of PRNP may be triggering of signalling cascades which contribute to cell-cell interactions and may act anti-apoptotically. Yet, in the heterogenous set of cells expressing PrP^C these pathways will contribute to a number of cell-specific phenotypes, such as the synaptic plasticity and activation of lymphoid cells.

Prion protein gene

Prion protein

Shadow of prion protein gene

Shadow protein

prions

prion diseases

Development of the new yeast-based assays for prion properties

Sun, Meng

29 August 2011

Prion is an infectious isoform of a normal cellular protein which is capable of converting the non-prion form of the same protein into the alternative prion form. Mammalian prion protein PrP is responsible for prion formation in mammals, causing a series of fatal and incurable prion diseases. (1) We constructed, for the first time, a two-component system to phenotypically monitor the conformational status of PrP in the yeast cells. In this system, the prion domain of Sup35 (Sup35N) was fused to PrP90-230, and the initial formation of the PrPSc-like conformation stimulated prion formation of Sup35N, which in turn converted soluble Sup35 into the prion isoform, leading to a detectable phenotype. Prion-like properties of PrP were studied in this novel yeast model system. Additionally, we employed this system to study amyloidogenic protein Aβ42 aggregation in the yeast model. It has been suggested that the ability to form transmissible amyloids (prions) is widespread among yeast proteins and is likely intrinsic to proteins from other organisms. However, the distribution of yeast prions in natural conditions is not yet clear, which prevents us from understanding the relationship between prions and their adaptive roles in various environmental conditions. (2) We modified and developed sequence and phenotype-independent approaches for prion detection and monitoring. We employed these approaches for prion-profiling among yeast strains of various origins. (3) Lastly, we found a prion-like state [MCS+] causing nonsense suppression in the absence of the Sup35 prion domain. Our results suggested that [MCS+] is determined by both a prion factor and a nuclear factor. The prion-related properties of [MCS+] were studied by genetic and biochemical approaches.

Amyloid beta

[PSI+]

Prion detection

Prion induction

Mammalian prion protein

Prions

Proteins

Prion diseases

Prion species barrier at the short phylogenetic distances in the yeast model

Chen, Buxin

07 July 2008

Prions are self-perpetuating and, in most cases, aggregation-prone protein isoforms that transmit neurodegenerative diseases in mammals and control heritable traits in yeast. Prion conversion requires a very high level of identity of the interacting protein sequences. Decreased transmission of the prion state between divergent proteins is termed "species barrier" and was thought to occur due to the inability of divergent prion proteins to co-aggregate. Species barrier can be overcome in cross-species infections, for example from "mad cows" to humans. We studied the counterparts of yeast prion protein Sup35, originated from three different species of the Saccharomyces sensu stricto group and exhibiting the range of prion domain divergence that overlaps with the range of divergence observed among distant mammalian species. Heterologous Sup35 proteins co-aggregated in S. cerevisiae cells. However, in vivo cross-species prion conversion was decreased and in vitro polymerization was cross-inhibited in at least some heterologous combinations, thus demonstrating the existence of prion species barrier. Our data suggests that species-specificity of prion transmission is controlled at the level of conformational transition rather than co-aggregation. We have shown the Sup35 prion domain is sufficient for the species barrier among the S. sensu stricto species, and constructed SUP35 chimeric prion domains, combining the subregions of various origins Our data demonstrated in different cross-species combinations, different modules of prion domain play a crucial role in the controlling of species-specificity of prion transmission. One essential amino acid position has been identified in S. cerevisiae and S. paradoxus system. Our data support a model suggesting that identity of the short amyloidogenic sequences is crucial for the species barrier. Sup35 originated from three different species of the S. sensu stricto group were capable of forming a prion in S. cerevisiae. However, it was not known whether they are capable of generating and maintaining the prion state in the homologous cell environment. We have constructed the S. paradoxus and S. bayanus strains with appropriate markers, and we were able to demonstrate de novo [PSI+] formation in S. paradoxus but not in S. bayanus. Our data show that [PSI+] formation is not a unique property of S. cerevisiae.

Species barrier

S. paradoxus

S. cerevisiae

Prion

S. bayanus

Prions

Prion diseases

Yeast

Communicable diseases

Folding of the Prion Protein

Apetri, Constantin Adrian

31 March 2004

No description available.

Biophysics, Medical

protein folding

prion diseases

prion protein

folding intermediate

salt effect

kinetics

stopped flow

Mort neuronale et maladies à prions / Neuronal death and prion diseases

Ragagnin, Audrey

11 December 2014

La conversion conformationnelle de la protéine prion cellulaire PrPC neuroprotectrice en protéine prion PrPSc infectieuse et pathogène caractérise les maladies à prions. Dans le cerveau infecté par les prions, la perte de PrPC, le gain de PrPSc neurotoxique et l’inflammation concourent à la mort neuronale par des mécanismes encore mal connus.Ces travaux valident les cultures organotypiques de cervelet de souris comme système expérimental ex vivo favorable à l’étude de ces mécanismes et montrent que l’absence de PrPC aussi bien que PrPSc activent des mécanismes apoptotiques et autophagiques qui conduisent à la mort des cellules de Purkinje du cervelet. Une deuxième étude in situ chez la souris montre que la compartimentation anatomo-fonctionnelle du cervelet est un paramètre endogène de la pathogenèse des prions de tremblante 22L. Une troisième série d’expériences in situ montre que les prions provoquent l’augmentation du récepteur TNFR1 de la cytokine pro-inflammatoire TNF-α à la membrane des astrocytes enveloppant les synapses excitatrices des cellules de Purkinje dans le cortex cérébelleux de souris infectées. Ceci implique une composante astrocytaire dans la réaction des complexes synaptiques aux prions. / The conversion of the protective cellular prion protein PrPC into an infectious, neurotoxic conformer PrPSc is a feature of prion diseases. In the prion-diseased brain, the loss of PrPC, the production of pathogenic PrPSc and inflammation contribute to neuronal death by still unknown mechanisms.The present results validate cerebellar organotypic cultures as a valuable experimental system to study ex vivo these mechanisms and provide insight into the apoptotic and autophagic processes activated by the absence of PrPC in Prnp-deficient mice and by PrPSc prions and lead to the death of the cerebellar Purkinje cells. A second line of research in situ showed that the anatomo-functional compartmentation of the mouse cerebellum is an endogenous parameter of the pathogenesis of the 22L scrapie prions. Finally, another in situ approach revealed that prions increase the levels of TNFR1, a receptor for the pro-inflammatory cytokine TNF-α at the membrane of the astrocytes enveloping Purkinje cell excitatory synapses in the cerebellar cortex of infected mice. This implies that the response of synaptic complexes to prions involves a glial component.

Maladies à prions

Cervelet

Neuroinflammation

Mort neuronale

Autophagie

Protéine Doppel

Prion diseases

Cerebellum

Neuroinflammation

Neuronal death

Autophagy

Doppel

579.29

572.6

616.83

Assessment of Retroviruses as Potential Vectors for the Cell Delivery of Prions

Rahimi Khameneh, Shabnam

31 October 2012

Transmissible spongiform encephalopathies (TSEs) or prion diseases are a class of fatal brain disorders better known as Creutzfeldt-Jacob Disease (CJD) in humans, bovine spongiform encephalopathy (BSE) in cattle, scrapie in sheep, and chronic wasting disease (CWD) in deer and elk. The infectious agent responsible for these diseases is a misfolded prion protein capable of catalyzing a conformational change in normal cellular prion proteins (PrPC) into aberrant disease-causing structural isoforms (PrPSc). Although the etiological agent for TSEs has clearly been defined as PrPSc, there are important gaps in our understanding of how these proteins target and invade brain tissue. It remains to be established how ingested PrPSc ultimately reach the brain and also to understand why these tissues are particularly targeted, notwithstanding that several other tissues highly express prion proteins. Certain viruses, retroviruses in particular, efficiently hijack host proteins and can carry these proteins with them when they are released from a cell. Several lines of evidence have shown that prions and retroviruses can interact and associate at various stages of the retroviral replication cycle. Of special interest is that most retroviruses can cross the blood-brain barrier and could therefore deliver host-derived proteins to neuronal cells. In view of these observations, this thesis investigates whether retroviruses can act as vectors to capture prions from an infected cell and deliver them to a susceptible target cell. In this work, I have cloned human and mouse prion cDNAs from PBMCs and the murine cell line NIH 3T3. Either a FLAG epitope tag or the eGFP reporter protein cDNA was inserted into a region of the prion cDNA that is predicted to be amenable to such genetic insertions without affecting protein folding or expression. I then confirmed using both fluorescent and confocal microscopy and that the recombinant proteins had a similar cell distribution to the endogenous prion protein. Using Western blot analysis, I then showed that endogenous and overexpressed prion proteins can be detected in co-transfected cells producing HIV and murine leukemia virus (MLV) retroviral particles. Finally, I went on to show that prions are also present at high levels in HIV and MLV retroviral particles released from these cells. This work constitutes the first step in determining whether retroviruses can act as vectors for prion dissemination. Establishing a strong and clear association between retroviruses, pathogenic prions and prion disease would provide the rationale for preventive measures to be taken directly against retroviruses in order to protect humans and animals that have been newly exposed to PrPSc-infected products or those who are genetically predisposed to develop prion diseases. Anti-retroviral drugs could also be potentially used to delay disease progression and reduce prion transmission in human and animal tissues. The availability of such a treatment would constitute a significant advancement because there is currently no cure or treatment for prion diseases.

Prion

Prion diseases

Retroviruses

MLV

HIV

Vector

FLAG epitope tag

eGFP reporter protein

Prion protein constructs

NIH3T3 cell

HEK 293T cell

Confocal fluorescent microscopy