Αnti-prion effects of anthocyanins.

Prion diseases, also known as Transmissible Spongiform Encephalopathies (TSEs), are protein-based neurodegenerative disorders (NDs) affecting humans and animals. They are characterized by the conformational conversion of the normal cellular prion protein, PrPC, into the pathogenic isoform, PrPSc. Prion diseases are invariably fatal and despite ongoing research, no effective prophylactic or therapeutic avenues are currently available. Anthocyanins (ACNs) are unique flavonoid compounds and interest in their use as potential neuroprotective and/or therapeutic agents against NDs, has increased significantly in recent years. Therefore, we investigated the potential anti-oxidant and anti-prion effects of Oenin and Myrtillin, two of the most common anthocyanins, using the most accepted in the field overexpressing PrPScin vitro model and a cell free protein aggregation model. Our results, indicate both anthocyanins as strong anti-oxidant compounds, upregulating the expression of genes involved in the anti-oxidant response, and reducing the levels of Reactive Oxygen Species (ROS), produced due to pathogenic prion infection, through the activation of the Keap1-Nrf2 pathway. Importantly, they showcased remarkable anti-prion potential, as they not only caused the clearance of pathogenic PrPSc aggregates, but also completely inhibited the formation of PrPSc fibrils in the Cerebrospinal Fluid (CSF) of patients with Creutzfeldt-Jakob disease (CJD). Therefore, Oenin and Myrtillin possess pleiotropic effects, suggesting their potential use as promising preventive and/or therapeutic agents in prion diseases and possibly in the spectrum of neurodegenerative proteinopathies.

Different tau fibril types reduce prion level in chronically and de novo infected cells.

Neurodegenerative diseases are often characterized by the codeposition of different amyloidogenic proteins, normally defining distinct proteinopathies. An example is represented by prion diseases, where the classical deposition of the aberrant conformational isoform of the prion protein (PrPSc) can be associated with tau insoluble species, which are usually involved in another class of diseases called tauopathies. How this copresence of amyloidogenic proteins can influence the progression of prion diseases is still a matter of debate. Recently, the cellular form of the prion protein, PrPC, has been investigated as a possible receptor of amyloidogenic proteins, since its binding activity with Aß, tau, and α-synuclein has been reported, and it has been linked to several neurotoxic behaviors exerted by these proteins. We have previously shown that the treatment of chronically prion-infected cells with tau K18 fibrils reduced PrPSc levels. In this work, we further explored this mechanism by using another tau construct that includes the sequence that forms the core of Alzheimer's disease tau filaments in vivo to obtain a distinct fibril type. Despite a difference of six amino acids, these two constructs form fibrils characterized by distinct biochemical and biological features. However, their effects on PrPSc reduction were comparable and probably based on the binding to PrPC at the plasma membrane, inhibiting the pathological conversion event. Our results suggest PrPC as receptor for different types of tau fibrils and point out a role of tau amyloid fibrils in preventing the pathological PrPC to PrPSc conformational change.

CSF biomarkers for prion diseases.

Recently, clinical trials of human prion disease (HPD) treatments have begun in many countries, and the therapeutic window of these trials focuses mainly on the early stage of the disease. Furthermore, few studies have examined the role of biomarkers at the early stage. According to the World Health Organization, the clinical diagnostic criteria for HPDs include clinical findings, cerebrospinal fluid (CSF) protein markers, and electroencephalography (EEG). In contrast, the UK and European clinical diagnostic criteria include a combination of clinical findings, 14-3-3 protein in the CSF, magnetic resonance imaging-diffusion-weighted imaging (MRI-DWI), and EEG. Moreover, recent advancements in laboratory testing and MRI-DWI have improved the accuracy of diagnostics used for prion diseases. However, according to MRI-DWI data, patients with rapidly progressing dementia are sometimes misdiagnosed with HPD due to the high-intensity areas detected in their brains. Thus, analyzing the CSF biomarkers is critical to diagnose accurately different diseases. CSF biomarkers are investigated using a biochemical approach or the protein amplification methods that utilize the unique properties of prion proteins and the ability of PrPSc to induce a conformational change. The biochemical markers include the 14-3-3 and total tau proteins of the CSF. In contrast, the protein amplification methods include the protein misfolding cyclic amplification assay and real-time quaking-induced conversion (RT-QuIC) assay. The RT-QuIC analysis of the CSF has been proved to be a highly sensitive and specific test for identifying sporadic HPD forms; for this reason, it was included in the diagnostic criteria.

Body-first Parkinson's disease and variant Creutzfeldt-Jakob disease - similar or different?

In several neurodegenerative disorders, proteins that typically exhibit an α-helical structure misfold into an amyloid conformation rich in ß-sheet content. Through a self-templating mechanism, these amyloids are able to induce additional protein misfolding, facilitating their propagation throughout the central nervous system. This disease mechanism was originally identified for the prion protein (PrP), which misfolds into PrPSc in a number of disorders, including variant Creutzfeldt-Jakob disease (vCJD) and bovine spongiform encephalopathy (BSE). More recently, the prion mechanism of disease was expanded to include other proteins that rely on this self-templating mechanism to cause progressive degeneration, including α-synuclein misfolding in Parkinson's disease (PD). Several studies now suggest that PD patients can be subcategorized based on where in the body misfolded α-synuclein originates, either the brain or the gut, similar to patients developing sporadic CJD or vCJD. In this review, we discuss the human and animal model data indicating that α-synuclein and PrPSc misfolding originates in the gut in body-first PD and vCJD, and summarize the data identifying the role of the autonomic nervous system in the gut-brain axis of both diseases.

A new model for sensitive detection of zoonotic prions by PrP transgenic Drosophila.

Prions are transmissible protein pathogens most reliably detected by a bioassay in a suitable host, typically mice. However, the mouse bioassay is slow and cumbersome, and relatively insensitive to low titers of prion infectivity. Prions can be detected biochemically in vitro by the protein misfolding cyclic amplification (PMCA) technique, which amplifies disease-associated prion protein but does not detect bona fide prion infectivity. Here, we demonstrate that Drosophila transgenic for bovine prion protein (PrP) expression can serve as a model system for the detection of bovine prions significantly more efficiently than either the mouse prion bioassay or PMCA. Strikingly, bovine PrP transgenic Drosophila could detect bovine prion infectivity in the region of a 10-12 dilution of classical bovine spongiform encephalopathy (BSE) inoculum, which is 106-fold more sensitive than that achieved by the bovine PrP mouse bioassay. A similar level of sensitivity was observed in the detection of H-type and L-type atypical BSE and sheep-passaged BSE by bovine PrP transgenic Drosophila. Bioassays of bovine prions in Drosophila were performed within 7 weeks, whereas the mouse prion bioassay required at least a year to assess the same inoculum. In addition, bovine PrP transgenic Drosophila could detect classical BSE at a level 105-fold lower than that achieved by PMCA. These data show that PrP transgenic Drosophila represent a new tractable prion bioassay for the efficient and sensitive detection of mammalian prions, including those of known zoonotic potential.

Generation, optimization and characterization of novel anti-prion compounds.

Prions are misfolded proteins involved in neurodegenerative diseases of high interest in veterinary and public health. In this work, we report the chemical space exploration around the anti-prion compound BB 0300674 in order to gain an understanding of its Structure Activity Relationships (SARs). A series of 43 novel analogues, based on four different chemical clusters, were synthetized and tested against PrPSc and mutant PrP toxicity assays. From this biological screening, two compounds (59 and 65) emerged with a 10-fold improvement in anti-prion activity compared with the initial lead compound, presenting at the same time interesting cell viability.

Understanding prion structure and conversion.

Since their original identification, prions have represented enigmatic agents that defy the classical concept of genetic inheritance. For almost four decades, the high-resolution structure of PrPSc, the infectious and misfolded counterpart of the cellular prion protein (PrPC), has remained elusive, mostly due to technical challenges posed by its high insolubility and aggregation propensity. As a result, such a lack of information has critically hampered the search for an effective therapy against prion diseases. Nevertheless, multiple attempts to get insights into the structure of PrPSc have provided important experimental constraints that, despite being at limited resolution, are paving the way for the application of computer-aided technologies to model the three-dimensional architecture of prions and their templated replication mechanism. Here, we review the most relevant studies carried out so far to elucidate the conformation of infectious PrPSc and offer an overview of the most advanced molecular models to explain prion structure and conversion.

Feasibility studies of radioiodinated pyridyl benzofuran derivatives as potential SPECT imaging agents for prion deposits in the brain.

INTRODUCTION: Prion diseases are fatal neurodegenerative disorders caused by the deposition of abnormal prion protein aggregates (PrPSc) in the central nervous system. This study aimed to evaluate the use of iodinated pyridyl benzofuran (IPBF) derivatives as single-photon emission computed tomography (SPECT) probes for the detection of cerebral PrPSc deposits. METHODS: In vitro binding assays of IPBF derivatives were carried out in the recombinant mouse prion protein (rMoPrP) and brain sections of mouse-adapted bovine spongiform encephalopathy (mBSE)-infected mice. SPECT imaging of 5-(5-[123I]iodobenzofuran-2-yl)-N-methylpyridin-2-amine ([123I]IPBF-NHMe) was performed on mBSE-infected and mock-infected mice. RESULTS: Fluorescence microscopy results showed that fluorescence signals of IPBF derivatives corresponded to the thioflavin-T positive amyloid deposits of PrPSc in the brain sections of mouse-adapted bovine spongiform encephalopathy (mBSE)-infected mice. Among the IPBF derivatives, 5-(5-iodobenzofuran-2-yl)-N-methylpyridin-2-amine (IPBF-NHMe) exhibited the highest binding affinity to the recombinant mouse prion protein (rMoPrP) aggregates with a Ki of 14.3 nM. SPECT/computed tomography (CT) imaging and ex vivo autoradiography demonstrated that the [123I]IPBF-NHMe distribution in brain tissues of mBSE-infected mice co-localized with PrPSc deposits. CONCLUSION: [123I]IPBF-NHMe appears to be a prospective SPECT tracer for monitoring prion deposits in living brain tissues.

[Effects of SGI-1027 on Formation and Elimination of PrP

Recently, SGI-1027, a well-known inhibitor of DNA-methyl transferases (DNMTs), was reported to effectively reduce formation of pathogenic PrP^(Sc) in prion-infected cells. Herein, we confirm the elimination of PrP^(Sc) in chronic wasting disease (CWD) prion-infected neurons by SGI-1027, and pinpoint the binding region of human prion protein to SGI-1027. SGI-1027 is broadly functional against various prion disease types, including human prions. Previously, the inhibitory effects of SGI-1027 on DNMT function is well tested in various cell culture models. While neither treatment with a DNMTs enhancer S-adenosyl-L-methionine (SAM), nor with their inhibitor, 5-azacytidine, prevented PrP^(Sc) propagation, SGI-1027 did. Our study suggest that the anti-prion effects of SGI-1027 are a result of its direct interaction with PrP^(C), which effectively interferes with the pathogenic conformational change of PrP^(C) to PrP^(Sc). We conclude that SGI-1027 driven suppression of pathogenic PrP^(Sc) is independent of DNMT.

Therapies for prion diseases.

Recent advances in understanding of the molecular biology of prion diseases and improved clinical diagnostic techniques might allow researchers to think about therapeutic trials in Creutzfeldt-Jakob disease (CJD) patients. Some attempts have been made in the past and various compounds have been tested in single case reports and patient series. Controlled trials are rare. However, in the past few years, it has been demonstrated that clinical trials are feasible. The clinicians might face several specific problems when evaluating the efficacy of the drug in CJD, such as rareness of the disease, lack of appropriate preclinical tests and heterogeneous clinical presentation in humans. These problems have to be carefully addressed in future.

Disassociation of ß1-α1-ß2 from the α2-α3 domain of prion protein (PrP) is a prerequisite for the conformational conversion of PrPC into PrPSc: Driven by the free energy landscape.

Misfolding of the cellular prion protein (PrPC) into ß-sheet-rich scrapie form (PrPSc) is associated with transmissible spongiform encephalopathies. A point mutation F198S is responsible for the development of a rare inherited Gerstmann-Straussler-Scheinker disease caused by the aggregation of PrPC. Thus, identification and the structural characterization of aggregation-prone regions are essential to delineate the conversion of PrPC to the disease-associated PrPSc upon F198S mutation. In the present study, molecular dynamics simulations on the wild-type PrP (WT-PrP) and its mutant were performed to explore the structural basis responsible for aggregation driven by the mutation. Secondary structure analysis revealed that the mutant exhibited a partial unfolding on α2 and the complete distortion in the 310-helix of the ß2-α2 loop. Remarkably, the ß2-α2 loop is in proximity to α3 attributed by the long-range hydrophobic interactions and such structural intimacy is not observed in the WT-PrP. Owing to this, the ß1-α1-ß2 regions have separated from α2-α3 domain resulting in the impairment on the hydrogen bond between α1 and α3. Thus, the present study provides a detailed structural description of the F198S mutant in line with previous experimental results and delivers insights into the structural basis responsible for the conversion of PrPC to the disease-associated PrPSc.

The retention of prion protein in the endoplasmic reticulum prevents N2A cells from proteasome inhibition-induced cytotoxicity.

Prion disease is a fatal neurodegenerative disease that may result from the conversion of normal cellular prion protein (PrPC) to the pathogenic scrapie PrP isoform (PrPSc), however, how proliferation of prion leads to neuronal apoptosis is still not clear. In this study, to explore the role of the endoplasmic reticulum (ER) in prion diseases, we engineered the KDEL ER-retention motif to the C-terminus of PrPC and studied its effect on N2A cell toxicity. The KDEL retention signal led to the accumulation of PrP in the ER, and KDEL signal could effectively deplete PrP from the cell surface and trap PrP in the ER/Cis-Golgi compartment. PrPC molecules were delayed in their transit along the early pathway of the secretory compartment, however, they did not aggregate, and were not resistant to Proteinase K (PK) or become detergent-insoluble. Moreover, we found that the ER was not the site where PrP became detergent-insoluble and acquired PK resistance. In addition, an MTT assay indicated cells expressing PrPC/N2A were sensitive to proteasome inhibition, but not N2A cells expressing PrPKDEL. Our findings suggest that the ER is not a compartment in which wild type PrPC is able to initiate aggregation, protease resistance or other scapie-like properties of PrP.

Development of radioiodinated acridine derivatives for in vivo imaging of prion deposits in the brain.

Prion diseases are caused by deposition of abnormal prion protein aggregates (PrPSc) in the central nervous system. This study aimed to develop in vivo imaging probes that can detect cerebral PrPSc deposits. We synthesized several quinacrine-based acridine (AC) derivatives with 2,9-substitution and radioiodinated them. The AC derivatives were evaluated as prion-imaging probes using recombinant mouse prion protein (rMoPrP) aggregates and brain sections of mouse-adapted bovine spongiform encephalopathy (mBSE)-infected mice. The distribution of these compounds in mice was also evaluated. The 2-methoxy derivative [125I]2 exhibited the highest binding affinity for rMoPrP aggregates with an equilibrium dissociation constant (Kd) value of 43.4nM. Fluorescence imaging with 2 showed clear signals at the thioflavin T (ThT)-positive amyloid deposits in the mBSE-infected mouse brain. Although a discrepancy was observed between the in vitro binding of AC derivatives to the aggregates and in vivo distribution of these compounds in the brain and we failed to identify prospective prion-imaging probes in this study, the AC derivatives may be considered a useful scaffold for the development of in vivo imaging probes. Further chemical modification of these AC derivatives may discover clinically applicable prion imaging probes.

Encefalopatia espongiforme bovina atípica: uma revisão / Atypical bovine spongiform encephalopathy: a review

A encefalopatia espongiforme bovina (EEB), causada por um príon infectante, surgiu na década de 1980 na Europa como uma nova doença nos rebanhos bovinos e, desde então, estão sendo tomadas várias ações para sua prevenção e controle. A restrição da alimentação de ruminantes com subprodutos de origem animal e a remoção e destruição dos materiais de risco específico para a doença das carcaças em frigoríficos se mostraram efetivas medidas para o controle da doença, além de reduzirem a exposição humana ao agente, pois se trata de uma importante zoonose. No entanto, em 2004 os primeiros casos atípicos de EEB foram diagnosticados, nos quais os agentes causais apresentavam alterações de peso molecular na prova de Western blot, em relação ao agente da forma clássica. Além das diferenças moleculares dos agentes, as apresentações clínicas mostraram-se diferenciadas nas formas atípicas, acometendo principalmente bovinos com idade superior a oito anos. Por se tratar de uma nova forma da doença, muitos estudos estão sendo conduzidos buscando elucidar a patogenia, epidemiologia e seu potencial zoonótico. Objetivou-se neste estudo revisar os principais aspectos relacionados às EEB atípicas enfatizando sua etiologia, epidemiologia, sinais clínicos, diagnóstico e medidas de controle.(AU)

Bovine spongiform encephalopathy (BSE), caused by an infectious prion, emerged in the 1980s in Europe as a new disease in cattle and, since then, several actions are being taken for its prevention and control. Restricting the feeding of ruminants with animal by-products and the removal and destruction of specific risk materials (SRM) for the condition of carcasses in slaughterhouses have been proven effective to control the disease, in addition to the reduction of human exposure to the agent, as this is an important zoonosis. However, in 2004 the first atypical cases of BSE were diagnosed, in which the causative agents showed different molecular weights in Western blot (WB), compared to the classical form of the agent. In addition to the molecular differences, clinical presentations proved to be differentiated in atypical forms, affecting mainly cattle older than eight years. Because it is a new form of the disease, many studies are being conducted to elucidate the pathogenesis, epidemiology and zoonotic potential of atypical BSE. The aim of this study was to review the main aspects of atypical BSE emphasizing its etiology, epidemiology, clinical signs, diagnosis and control and prevention measures.(AU)

Encefalopatia espongiforme bovina atípica: uma revisão / Atypical bovine spongiform encephalopathy: a review

Bovine spongiform encephalopathy (BSE), caused by an infectious prion, emerged in the 1980s in Europe as a new disease in cattle and, since then, several actions are being taken for its prevention and control. Restricting the feeding of ruminants with animal by-products and the removal and destruction of specific risk materials (SRM) for the condition of carcasses in slaughterhouses have been proven effective to control the disease, in addition to the reduction of human exposure to the agent, as this is an important zoonosis. However, in 2004 the first atypical cases of BSE were diagnosed, in which the causative agents showed different molecular weights in Western blot (WB), compared to the classical form of the agent. In addition to the molecular differences, clinical presentations proved to be differentiated in atypical forms, affecting mainly cattle older than eight years. Because it is a new form of the disease, many studies are being conducted to elucidate the pathogenesis, epidemiology and zoonotic potential of atypical BSE. The aim of this study was to review the main aspects of atypical BSE emphasizing its etiology, epidemiology, clinical signs, diagnosis and control and prevention measures.

A encefalopatia espongiforme bovina (EEB), causada por um príon infectante, surgiu na década de 1980 na Europa como uma nova doença nos rebanhos bovinos e, desde então, estão sendo tomadas várias ações para sua prevenção e controle. A restrição da alimentação de ruminantes com subprodutos de origem animal e a remoção e destruição dos materiais de risco específico para a doença das carcaças em frigoríficos se mostraram efetivas medidas para o controle da doença, além de reduzirem a exposição humana ao agente, pois se trata de uma importante zoonose. No entanto, em 2004 os primeiros casos atípicos de EEB foram diagnosticados, nos quais os agentes causais apresentavam alterações de peso molecular na prova de Western blot, em relação ao agente da forma clássica. Além das diferenças moleculares dos agentes, as apresentações clínicas mostraram-se diferenciadas nas formas atípicas, acometendo principalmente bovinos com idade superior a oito anos. Por se tratar de uma nova forma da doença, muitos estudos estão sendo conduzidos buscando elucidar a patogenia, epidemiologia e seu potencial zoonótico. Objetivou-se neste estudo revisar os principais aspectos relacionados às EEB atípicas enfatizando sua etiologia, epidemiologia, sinais clínicos, diagnóstico e medidas de controle.

Proteinase K and the structure of PrPSc: The good, the bad and the ugly.

Infectious proteins (prions) are, ironically, defined by their resistance to proteolytic digestion. A defining characteristic of the transmissible isoform of the prion protein (PrP(Sc)) is its partial resistance to proteinase K (PK) digestion. Diagnosis of prion disease typically relies upon immunodetection of PK-digested PrP(Sc) by Western blot, ELISA or immunohistochemical detection. PK digestion has also been used to detect differences in prion strains. Thus, PK has been a crucial tool to detect and, thereby, control the spread of prions. PK has also been used as a tool to probe the structure of PrP(Sc). Mass spectrometry and antibodies have been used to identify PK cleavage sites in PrP(Sc). These results have been used to identify the more accessible, flexible stretches connecting the ß-strand components in PrP(Sc). These data, combined with physical constraints imposed by spectroscopic results, were used to propose a qualitative model for the structure of PrP(Sc). Assuming that PrP(Sc) is a four rung ß-solenoid, we have threaded the PrP sequence to satisfy the PK proteolysis data and other experimental constraints.

Subcellular distribution of the prion protein in sickness and in health.

The cellular prion protein (PrP(C)) is an ubiquitously expressed glycoprotein that is most abundant in the central nervous system. It is thought to play a role in many cellular processes, including neuroprotection, but may also contribute to Alzheimer's disease and some cancers. However, it is best known for its central role in the prion diseases, such as Creutzfeldt-Jakob disease (CJD), bovine spongiform encephalopathy (BSE), and scrapie. These protein misfolding diseases can be sporadic, acquired, or genetic and are caused by refolding of endogenous PrP(C) into a beta sheet-rich, pathogenic form, PrP(Sc). Once prions are present in the central nervous system, they increase and spread during a long incubation period that is followed by a relatively short clinical disease phase, ending in death. PrP molecules can be broadly categorized as either 'good' (cellular) PrP(C) or 'bad' (scrapie prion-type) PrP(Sc), but both populations are heterogeneous and different forms of PrP(C) may influence various cellular activities. Both PrP(C) and PrP(Sc) are localized predominantly at the cell surface, with the C-terminus attached to the plasma membrane via a glycosyl-phosphatidylinositol (GPI) anchor and both can exist in cleaved forms. PrP(C) also has cytosolic and transmembrane forms, and PrP(Sc) is known to exist in a variety of conformations and aggregation states. Here, we discuss the roles of different PrP isoforms in sickness and in health, and show the subcellular distributions of several forms of PrP that are particularly relevant for PrP(C) to PrP(Sc) conversion and prion-induced pathology in the hippocampus.

Prion degradation pathways: Potential for therapeutic intervention.

Prion diseases are fatal neurodegenerative disorders. Pathology is closely linked to the misfolding of native cellular PrP(C) into the disease-associated form PrP(Sc) that accumulates in the brain as disease progresses. Although treatments have yet to be developed, strategies aimed at stimulating the degradation of PrP(Sc) have shown efficacy in experimental models of prion disease. Here, we describe the cellular pathways that mediate PrP(Sc) degradation and review possible targets for therapeutic intervention. This article is part of a Special Issue entitled 'Neuronal Protein'.

Reduced expression of the presynaptic co-chaperone cysteine string protein alpha (CSPα) does not exacerbate experimentally-induced ME7 prion disease.

Infection of mice with the ME7 prion agent results in well-characterised neuropathological changes, which includes vacuolation, neurodegeneration and synaptic degeneration. Presynaptic dysfunction and degeneration is apparent through the progressive reduction in synaptic vesicle proteins and eventual loss of synapses. Cysteine string protein alpha (CSPα), which regulates refolding pathways at the synapse, exhibits an early decline during chronic neurodegeneration implicating it as a mediator of disease mechanisms. CSPα null mice develop a progressive neuronal dysfunction through disruption of the integrity of presynaptic function. In this study, we investigated whether reduced expression of CSPα would exacerbate ME7 prion disease. Wild type (+/+) and heterozygous (+/-) mice, which express about a ∼50% reduction in CSPα, were used as a distinct genetic background on which to impose prion disease. +/+ and +/ - mice were inoculated with brain homogenate from either a normal mouse brain (NBH) or from the brain of a mouse which displayed clinical signs of prion disease (ME7). Behavioural tests, western blotting and immunohistochemistry, which resolve key elements of synaptic dysfunction, were used to assess the effect of reduced CSPα on disease. Behavioural tests revealed no change in the progression of disease in ME7-CSPα +/- animals compared to ME7-CSPα +/+ animals. In addition, the accumulation of misfolded PrP(Sc), the diseased associated gliosis or synaptic loss were not different. Thus, the misfolding events that generate synaptic dysfunction and lead to synaptic loss are unlikely to be mediated by a disease associated decrease in the refolding pathways associated with CSPα.