A novel seven-octapeptide repeat insertion in the prion protein gene (PRNP) in a Dutch pedigree with Gerstmann�CStr?ussler�CScheinker disease phenotype: comparison with similar cases from the literature

Human prion diseases can be sporadic, inherited or acquired by infection and show considerable phenotypic heterogeneity. We describe the clinical, histopathological and pathological prion protein (PrP^Sc) characteristics of a Dutch family with a novel 7-octapeptide repeat insertion (7-OPRI) in PRNP, the gene encoding the prion protein (PrP). Clinical features were available in four, neuropathological features in three and biochemical characteristics in two members of this family. The clinical phenotype was characterized by slowly progressive cognitive decline, personality change, lethargy, depression with anxiety and panic attacks, apraxia and a hypokinetic-rigid syndrome. Neuropathological findings consisted of numerous multi- and unicentric amyloid plaques throughout the cerebrum and cerebellum with varying degrees of spongiform degeneration. Genetic and molecular studies were performed in two male family members. One of them was homozygous for valine and the other heterozygous for methionine and valine at codon 129 of PRNP. Sequence analysis identified a novel 168?bp insertion [R2?CR2?CR2?CR2?CR3g?CR2?CR2] in the octapeptide repeat region of PRNP. Both patients carried the mutation on the allele with valine at codon 129. Western blot analysis showed type 1 PrP^Sc in both patients and detected a smaller ~8?kDa PrP^Sc fragment in the cerebellum in one patient. The features of this Dutch kindred define an unusual neuropathological phenotype and a novel PRNP haplotype among the previously documented 7-OPRI mutations, further expanding the spectrum of genotype?Cphenotype correlations in inherited prion diseases.     

Genetic Creutzfeldt-Jakob disease associated with the E200K mutation: characterization of a complex proteinopathy

The E200K mutation is the most frequent prion protein gene (PRNP) mutation detected worldwide that is associated with Creutzfeldt-Jakob disease (CJD) and thought to have overlapping features with sporadic CJD, yet detailed neuropathological studies have not been reported. In addition to the prion protein, deposition of tau, ??-synuclein, and amyloid-?? has been reported in human prion disease. To describe the salient and concomitant neuropathological alterations, we performed a systematic clinical, neuropathological, and biochemical study of 39 individuals carrying the E200K PRNP mutation originating from different European countries. The most frequent clinical symptoms were dementia and ataxia followed by myoclonus and various combinations of further symptoms, including vertical gaze palsy and polyneuropathy. Neuropathological examination revealed relatively uniform anatomical pattern of tissue lesioning, predominating in the basal ganglia and thalamus, and also substantia nigra, while the deposition of disease-associated PrP was more influenced by the codon 129 constellation, including different or mixed types of PrP^res detected by immunoblotting. Unique and prominent intraneuronal PrP deposition involving brainstem nuclei was also noted. Systematic examination of protein depositions revealed parenchymal amyloid-?? in 53.8%, amyloid angiopathy (A??) in 23.1%, phospho-tau immunoreactive neuritic profiles in 92.3%, neurofibrillary degeneration in 38.4%, new types of tau pathology in 33.3%, and Lewy-type ??-synuclein pathology in 15.4%. TDP-43 and FUS immunoreactive protein deposits were not observed. This is the first demonstration of intensified and combined neurodegeneration in a genetic prion disease due to a single point mutation, which might become an important model to decipher the molecular interplay between neurodegeneration-associated proteins.     

Prion disease with a 144 base pair insertion: unusual cerebellar prion protein immunoreactivity

Sporadic, acquired, and genetic human prion diseases are characterized neuropathologically by distinct deposition patterns of the abnormal, disease-associated form of the prion protein (PrP^sc). In addition to mutations in the prion protein gene (PRNP), PrP^sc immunostaining patterns correlate with molecular phenotypes of prion diseases defined by the PRNP polymorphism at codon 129 and with protease-resistant PrP classified by Western blotting. Some point or insertional PRNP mutations share similar clinical and neuropathological phenotypes, whereas others show great variability even within the same family. Here we report a patient who presented clinically as sporadic Creutzfeldt-Jakob disease (CJD). Histologically moderate spongiform change was seen in cerebral and cerebellar cortical areas. Neuronal loss was restricted mainly to the occipital cortex and the basal ganglia. Surprisingly, numerous eosinophilic globular structures were noted in the molecular layer and the parahippocampal gyrus. These globules showed intense PrP immunopositivity using anti-PrP antibodies against different epitopes. They were stained with PAS but lacked congophilia and birefringence in polarized light. Ultrastructurally, globules were composed of 21-nm-thick intermingled filaments without dense core. Genetic analysis revealed a PRNP 144 base pair insertion. Our case reinforces the importance of molecular genetic diagnosis, especially in those patients who lack a family history of prion disease and show unusual neuropathological changes. It also widens the phenotypic spectrum of prion diseases. The phenotypic variability within the same mutation suggests further, yet uncharacterized, genetic or epigenetic influence on phenotype in these diseases.     

Creutzfeldt-Jakob disease in a patient with an R208H mutation of the prion protein gene (PRNP) and a 17-kDa prion protein fragment

A case of Creutzfeldt-Jakob disease (CJD) with a rare mutation of the prion protein (PrP) gene (PRNP) at codon 208 (R208H) is described. By comparison with two preceding reports, the case described here displayed two distinct biochemical and neuropathological features. Western blot analysis of brain homogenates showed, in addition to the commonly observed three bands of abnormal protease-resistant PrP isoform (PrP^Sc), an additional band of about 17 kDa. Neuropathological examination of the post mortem brain revealed tau pathology in the hippocampus and entorhinal cortex, as well as ballooned neurons in the cortex, hippocampus and subcortical gray matter.     

Sporadic fatal insomnia with spongiform degeneration in the thalamus and widespread PrPSc deposits in the brain

We report a case of human prion disease of 29 months duration in a 74‐year‐old Japanese man. The disease started with progressive sleeplessness and dementia. MRI showed gradually progressive cerebral atrophy. Neuronal loss, spongiform change and gliosis were evident in the thalamus and cerebral cortex, as well as in the striatum and amygdaloid nucleus. In the cerebellar cortex, mild‐to‐moderate depletion of Pukinje cells and spongiform change were observed. Mild neuronal loss in the inferior olivary nucleus was also seen. Immunohistochemistry revealed widespread perivacuolar deposits of abnormal prion protein (PrP^Sc) in the cerebral cortex, thalamus, basal ganglia, and brainstem, and minimal plaque‐like deposits of PrP^Sc in the cerebellar cortex. In the cerebellar plaque‐like deposits, the presence of amyloid fibrils was confirmed ultrastructurally. The entire pathology appeared to lie halfway between those of CJD and fatal insomnia, and further demonstrated the relationship between spongiform degeneration and PrP^Sc deposits, especially in the diseased thalamus. By immunoblotting, the thalamus was shown to contain the lowest amount of PrP^SC among the brain regions examined. The PrP^Sc of type 2, in which the ratio of the three glycoforms was compatible with that of sporadic fatal insomnia (MM2‐thalamic variant) reported previously, was also demonstrated. Analysis of the prion protein gene (PRNP) showed no mutation, and homozygosity for methionine at codon 129. In conclusion, we considered that this patient had been suffering from sporadic, pathologically atypical fatal insomnia.     

Molecular biology and pathology of prion strains in sporadic human prion diseases

Prion diseases are believed to propagate by the mechanism involving self-perpetuating conformational conversion of the normal form of the prion protein, PrP^C, to the misfolded, pathogenic state, PrP^Sc. One of the most intriguing aspects of these disorders is the phenomenon of prion strains. It is believed that strain properties are fully encoded in distinct conformations of PrP^Sc. Strains are of practical relevance to human prion diseases as their diversity may explain the unusual heterogeneity of these disorders. The first insight into the molecular mechanisms underlying heterogeneity of human prion diseases was provided by the observation that two distinct disease phenotypes and their associated PrP^Sc conformers co-distribute with distinct PrP genotypes as determined by the methionine/valine polymorphism at codon 129 of the PrP gene. Subsequent studies identified six possible combinations of the three genotypes (determined by the polymorphic codon 129) and two common PrP^Sc conformers (named types 1 and 2) as the major determinants of the phenotype in sporadic human prion diseases. This scenario implies that each 129 genotype–PrP^Sc type combination would be associated with a distinct disease phenotype and prion strain. However, notable exceptions have been found. For example, two genotype–PrP^Sc type combinations are linked to the same phenotype, and conversely, the same combination was found to be associated with two distinct phenotypes. Furthermore, in some cases, PrP^Sc conformers naturally associated with distinct phenotypes appear, upon transmission, to lose their phenotype-determining strain characteristics. Currently it seems safe to assume that typical sporadic prion diseases are associated with at least six distinct prion strains. However, the intrinsic characteristics that distinguish at least four of these strains remain to be identified.     

On the biology of prions

Summary Prions cause scrapie and Creutzfeldt-Jakob disease (CJD); these infectious pathogens are composed largely, if not entirely, of protein molecules. No prion-specific polynucleotide has been identified. Purified preparations of scrapie prions contain high titers (10^9.5 ID₅₀/ml), one protein (PrP 27-30) and amyloid rods (10–20 nm in diameter ×100–200 nm in length). Considerable evidence indicates that PrP 27-30 is required for and inseparable from scrapie infectivity. PrP 27-30 is encoded by a cellular gene and is derived from a larger protein, denoted PrP^Sc or PrP 33-35^Sc, by protease digestion. A cellular isoform, designated PrP^C or PrP 33-35^C, is encoded by the same gene as PrP^Sc and both proteins appear to be translated from the same 2.1 kb mRNA. Monoclonal antibodies to PrP 27-30, as well as antisera to PrP synthetic peptides, specifically react with both PrP^C and PrP^Sc, establishing their relatedness. PrP^C is digested by proteinase K, while PrP^Sc is converted to PrP 27-30 under the same conditions. Prion proteins are synthesized with signal peptides and are integrated into membranes. Detergent extraction of microsomal membranes isolated from scrapie-infected hamster brains solubilizes PrP^C but induces PrP^Sc to polymerize into amyloid rods. This procedure allows separation of the two prion protein isoforms and the demonstration that PrP^Sc accumulates during scrapie infection, while the level of PrP^C does not change. The prion amyloid rods generated by detergent extraction are identical morphologically, except for length, to extracellular collections of prion amyloid filaments which form plaques in scrapie- and CJD-infected brains. The prion amyloid plaques stain with antibodies to PrP 27-30 and PrP peptides. PrP 33-35^C does not accumulate in the extracellular space. Prion rods composed of PrP 27-30 can be dissociated into phospholipid vesicles with full retention of scrapie infectivity. The murine PrP gene (Prn-p) is linked to thePrn-i gene which controls the length of the scrapie incubation period. Prolonged incubation times are a cardinal feature of scrapie and CJD. While the central role of PrP^Sc in scrapie pathogenesis is well established, the chemical as well as conformational differences between PrP^C and PrP^Sc are unknown but probably arise from post-translational modifications.Supported by research grants from the National Institutes of Health (AG 02132 and NS 14069) and a Senator Jacob Javits Center of Excellence in Neuroscience (NS 22786) as well as by gifts from RJR-Nabisco, Inc. and Sherman Fairchild FoundationThis review is based upon a plenary lecture entitled Biology and Neuropathology of Prions presented at the Xth International Congress of Neuropathology, Stockholm, Sweden, September 11, 1986, and is dedicated to the memory of Peter Wilhelm Lampert (1929–1986)     

An autopsy case of Creutzfeldt‐Jakob disease with a V180I mutation of the PrP gene and Alzheimer‐type pathology

We report an autopsy case of Creutzfeldt‐Jakob disease with a codon 180 point mutation of the prion protein gene (PRNP). A 77‐year‐old woman developed gait instability, followed by dementia and limb/truncal ataxia. She became akinetic and mute 18 months and died of pneumonia 26 months after the disease onset. Analysis of the PRNP gene revealed a codon 180 point mutation. Post‐mortem examination revealed marked spongiosis, neuronal loss, and astrocytic gliosis in the cerebral cortex. Mild to moderate spongiosis and neuronal loss were observed in the limbic cortex and basal ganglia. There was no spongiform change in the hippocampus, brain stem or cerebellum. Many senile plaques and neurofibrillary tangles were found, and the Braak stages were stage C and stage IV, respectively. Immunostaining for prion protein (PrP) revealed granular (synaptic‐type) and patchy PrP deposition in the cerebral cortex and especially in the hippocampus. Most patchy PrP deposits were colocalized with amyloid β plaques, but some of them were isolated. The relatively strong PrP deposition and coexistence of Alzheimer‐type pathology of this case are remarkable. We suppose that amyloid β plaques might act as a facilitating factor for PrP deposition.     

A case of sporadic Creutzfeldt-Jakob disease with a Gerstmann-Sträussler-Scheinker phenotype but no alterations in the PRNP gene

We report here an unusual sporadic case of Creutzfeldt-Jakob disease (CJD) characterized by an abundance of prion protein (PrP)-immunopositive kuru and multicentric but not florid plaques. Molecular genetic analysis of the PRNP open reading frame region spanning codons 8–221 was performed. Neither deletion nor insertion mutations were detected in the repeat area of the PRNP. No pathogenic mutation was found in the sequenced region between codon 108–221. Restriction analysis of the amplified fragment using restriction endonucleases DdeI, PvuII and AluI did not show any of the previously described pathogenic mutations at codon 102, 105, and 117 associated with Gerstmann-Sträussler-Scheinker (GSS). The patient was heterozygous for the methionine/valine coding triplet at polymorphic codon 129 of the PRNP gene by sequence, restriction endonuclease analysis and hybridization with allele-specific nucleotides. Furthermore, hybridization with ³²P-labeled allele-specific oligonucleotides confirmed the absence of pathogenic mutations at codons 102, 200 and 178. Such a case may present a missing “link” between sporadic CJD and familial GSS.     

Codon 129 polymorphism and the E200K mutation do not affect the cellular prion protein isoform composition in the cerebrospinal fluid from patients with Creutzfeldt–Jakob disease

The cellular prion protein (PrP^c) is a multifunctional, highly conserved and ubiquitously expressed protein. It undergoes a number of modifications during its post‐translational processing, resulting in different PrP^c glycoforms and truncated PrP^c fragments. Limited data are available in humans on the expression and cleavage of PrP^c. In this study we investigated the PrP^c isoform composition in the cerebrospinal fluid from patients with different human prion diseases. The first group of patients was affected by sporadic Creutzfeldt–Jakob disease exhibiting different PrP codon 129 genotypes. The second group contained patients with a genetic form of Creutzfeldt–Jakob disease (E200K). The third group consisted of patients with fatal familial insomnia and the last group comprised cases with the Gerstmann–Sträussler–Scheinker syndrome. We examined whether the PrP codon 129 polymorphism in sporadic Creutzfeldt–Jakob disease as well as the type of prion disease in human patients has an impact on the glycosylation and processing of PrP^c. Immunoblotting analyses using different monoclonal PrP^c antibodies directed against various epitopes of PrP^c revealed, for all examined groups of patients, a consistent predominance of the glycosylated PrP^c isoforms as compared with the unglycosylated form. In addition, the antibody SAF70 recognized a variety of PrP^c fragments with sizes of 21, 18, 13 and 12 kDa. Our findings indicate that the polymorphisms at PrP codon 129, the E200K mutation at codon 200 or the examined types of human transmissible spongiform encephalopathies do not exert a measurable effect on the glycosylation and processing of PrP^c in human prion diseases.     

Neuropathological and biochemical criteria to identify acquired Creutzfeldt‐Jakob disease among presumed sporadic cases

As an experimental model of acquired Creutzfeldt‐Jakob disease (CJD), we performed transmission studies of sporadic CJD using knock‐in mice expressing human prion protein (PrP). In this model, the inoculation of the sporadic CJD strain V2 into animals homozygous for methionine at polymorphic codon 129 (129 M/M) of the PRNP gene produced quite distinctive neuropathological and biochemical features, that is, widespread kuru plaques and intermediate type abnormal PrP (PrP^Sc). Interestingly, this distinctive combination of molecular and pathological features has been, to date, observed in acquired CJD but not in sporadic CJD. Assuming that these distinctive phenotypic traits are specific for acquired CJD, we revisited the literature and found two cases showing widespread kuru plaques despite the 129 M/M genotype, in a neurosurgeon and in a patient with a medical history of neurosurgery without dura mater grafting. By Western blot analysis of brain homogenates, we revealed the intermediate type of PrP^Sc in both cases. Furthermore, transmission properties of brain extracts from these two cases were indistinguishable from those of a subgroup of dura mater graft‐associated iatrogenic CJD caused by infection with the sporadic CJD strain V2. These data strongly suggest that the two atypical CJD cases, previously thought to represent sporadic CJD, very likely acquired the disease through exposure to prion‐contaminated brain tissues. Thus, we propose that the distinctive combination of 129 M/M genotype, kuru plaques, and intermediate type PrP^Sc, represents a reliable criterion for the identification of acquired CJD cases among presumed sporadic cases.     

Novel Compounds Identified by Structure-Based Prion Disease Drug Discovery Using In Silico Screening Delay the Progression of an Illness in Prion-Infected Mice

The accumulation of abnormal prion protein (PrP^Sc) produced by the structure conversion of PrP (PrP^C) in the brain induces prion disease. Although the conversion process of the protein is still not fully elucidated, it has been known that the intramolecular chemical bridging in the most fragile pocket of PrP, known as the “hot spot,” stabilizes the structure of PrP^C and inhibits the conversion process. Using our original structure-based drug discovery algorithm, we identified the low molecular weight compounds that predicted binding to the hot spot. NPR-130 and NPR-162 strongly bound to recombinant PrP in vitro, and fragment molecular orbital (FMO) analysis indicated that the high affinity of those candidates to the PrP is largely dependent on nonpolar interactions, such as van der Waals interactions. Those NPRs showed not only significant reduction of the PrP^Sc levels but also remarkable decrease of the number of aggresomes in persistently prion-infected cells. Intriguingly, treatment with those candidate compounds significantly prolonged the survival period of prion-infected mice and suppressed prion disease-specific pathological damage, such as vacuole degeneration, PrP^Sc accumulation, microgliosis, and astrogliosis in the brain, suggesting their possible clinical use. Our results indicate that in silico drug discovery using NUDE/DEGIMA may be widely useful to identify candidate compounds that effectively stabilize the protein.Electronic supplementary materialThe online version of this article (10.1007/s13311-020-00903-9) contains supplementary material, which is available to authorized users.     

Mutant prion protein D202N associated with familial prion disease is retained in the endoplasmic reticulum and forms ‘curly’ intracellular aggregates

Transmissible Spongiform Encephalopathies are fatal neurodegenerative disorders of humans and animals that are familial, sporadic, and infectious in nature. Familial disorders of humans include Gerstmann–Straussler–Scheinker disease (GSS), familial Creutzfeldt–Jakob disease (CJD), and fatal familial insomnia, and result from point mutations in the prion protein gene. Although neurotoxicity in familial cases is believed to result from a spontaneous change in conformation of mutant prion protein (PrP) to the pathogenic PrP-scrapie (PrP^Sc) form, emerging evidence indicates otherwise. We have investigated the processing and metabolism of mutant PrP D202N (PrP^202N) in cell models to elucidate possible mechanisms of cytotoxicity. In this report, we demonstrate that PrP^202N expressed in human neuroblastoma cells fails to achieve a mature conformation following synthesis and accumulates in the endoplasmic reticulum as ‘curly’ aggregates. In addition, PrP^202N cells show increased sensitivity to free radicals, indicating that neuronal susceptibility to oxidative damage may account for the neurotoxicity observed in cases of GSS resulting from PrP D202N mutation. Yaping Gu and Susamma Verghese contributed equally.     

Intracellular mechanisms mediating the neuronal death and astrogliosis induced by the prion protein fragment 106–126

Prion encephalopathies include fatal diseases of the central nervous system of men and animals characterized by nerve cell loss, glial proliferation and deposition of amyloid fibrils into the brain. During these diseases a cellular glycoprotein (the prion protein, PrP^C) is converted, through a not yet completely clear mechanism, in an altered isoform (the prion scrapie, PrP^Sc) that accumulates within the brain tissue by virtue of its resistance to the intracellular catabolism. PrP^Sc is believed to be responsible for the neuronal loss that is observed in the prion disease. The PrP 106–126, a synthetic peptide that has been obtained from the amyloidogenic portion of the prion protein, represents a suitable model for studying the pathogenic role of the PrP^Sc, retaining, in vitro, some characteristics of the entire protein, such as the capability to aggregate in fibrils, and the neurotoxicity. In this work we present the results we have recently obtained regarding the action of the PrP 106–126 in different cellular models. We report that the PrP 106–126 induces proliferation of cortical astrocytes, as well as degeneration of primary cultures of cortical neurons or of neuroectodermal stable cell lines (GH₃ cells). In particular, these two opposite effects are mediated by the same attitude of the peptide to interact with the L-type calcium channels: in the astrocytes, the activity of these channels seems to be activated by PrP 106–126, while, in the cortical neurons and in the GH₃ cells, the same treatment causes a blockade of these channels causing a toxic effect.     

An autopsied case of MM1 + MM2‐cortical with thalamic‐type sporadic Creutzfeldt‐Jakob disease presenting with hyperintensities on diffusion‐weighted MRI before clinical onset

A 78‐year‐old Japanese man presented with rapidly progressive dementia and gait disturbances. Eight months before the onset of clinical symptoms, diffusion‐weighted magnetic resonance imaging (DWI) demonstrated hyperintensities in the right temporal, right parietal and left medial occipital cortices. Two weeks after symptom onset, DWI showed extensive hyperintensity in the bilateral cerebral cortex, with regions of higher brightness that existed prior to symptom onset still present. Four weeks after clinical onset, periodic sharp wave complexes were identified on an electroencephalogram. Myoclonus was observed 8 weeks after clinical onset. The patient reached an akinetic mutism state and died 5 months after onset. Neuropathological examination showed widespread cerebral neocortical involvement of fine vacuole‐type spongiform changes with large confluent vacuole‐type spongiform changes. Spongiform degeneration with neuron loss and hypertrophic astrocytosis was also observed in the striatum and medial thalamus. The inferior olivary nucleus showed severe neuron loss with hypertrophic astrocytosis. Prion protein (PrP) immunostaining showed widespread synaptic‐type PrP deposition with perivacuolar‐type PrP deposition in the cerebral neocortex. Mild to moderate PrP deposition was also observed extensively in the basal ganglia, thalamus, cerebellum and brainstem, but it was not apparent in the inferior olivary nucleus. PrP gene analysis showed no mutations, and polymorphic codon 129 showed methionine homozygosity. Western blot analysis of protease‐resistant PrP showed both type 1 scrapie type PrP (PrP^Sc) and type 2 PrP^Sc. Based on the relationship between the neuroimaging and pathological findings, we speculated that cerebral cortical lesions with large confluent vacuoles and type 2 PrP^Sc would show higher brightness and continuous hyperintensity on DWI than those with fine vacuoles and type 1 PrP^Sc. We believe the present patient had a combined form of MM1 + MM2‐cortical with thalamic‐type sporadic Creutzfeldt‐Jakob disease (sCJD), which suggests a broader spectrum of sCJD clinicopathological findings.     

Polyunsaturated Fatty Acids Protect Against Prion-Mediated Synapse Damage In Vitro

A loss of synapses is characteristic of the early stages of the prion diseases. Here we modelled the synapse damage that occurs in prion diseases by measuring the amount of synaptophysin, a pre-synaptic membrane protein essential for neurotransmission, in cortical or hippocampal neurones incubated with the disease associated isoform of the prion protein (PrP^Sc), or with the prion-derived peptide PrP82-146. The addition of PrP^Sc or PrP82-146 caused a dose-dependent reduction in the synaptophysin content of PrP wildtype neurones indicative of synapse damage. They did not affect the synaptophysin content of PrP null neurones. The loss of synaptophysin in PrP wildtype neurones was preceded by the accumulation of PrP82-146 within synapses. Since supplements containing polyunsaturated fatty acids (PUFA) are frequently taken for their perceived health benefits including reported amelioration of neurodegenerative conditions, the effects of some common PUFA on prion-mediated synapse damage were examined. Pre-treatment of cortical or hippocampal neurones with docosahexaenoic (DHA) or eicosapentaenoic acids (EPA) protected neurones against the loss of synaptophysin induced by PrP82-146 or PrP^Sc. This effect of DHA and EPA was selective as they did not alter the loss of synaptophysin induced by a snakevenom neurotoxin. The effects of DHA and EPA were associated with a significant reduction in the amount of FITC-PrP82-146 that accumulated within synapses. Such observations raise the possibility that supplements containing PUFA may protect against the synapse damage and cognitive loss seen during the early stages of prion diseases.     

Accumulation of prion protein in the vagus nerve in creutzfeldt–jakob disease

Disease‐associated proteins are thought to propagate along neuronal processes in neurodegenerative diseases. To detect disease‐associated prion protein (PrP^Sc) in the vagus nerve in different forms and molecular subtypes of Creutzfeldt–Jakob disease (CJD), we applied 3 different anti‐PrP antibodies. We screened the vagus nerve in 162 sporadic and 30 genetic CJD cases. Four of 31 VV‐2 type sporadic CJD and 7 of 30 genetic CJD cases showed vagal PrP^Sc immunodeposits with distinct morphology. Thus, PrP^Sc in CJD affects the vagus nerve analogously to α‐synuclein in Parkinson disease. The morphologically diverse deposition of PrP^Sc in genetic and sporadic CJD argues against uniform mechanisms of propagation of PrP^Sc. Ann Neurol 2019;85:782–787     

Autopsied case of sporadic Creutzfeldt–Jakob disease classified as MM1+2C‐type

We encountered an autopsy case of sporadic Creutzfeldt‐Jakob disease (CJD) pathologically classified as MM1+2C‐type, where Western blot analysis of prion protein (PrP) mainly showed type‐1 scrapie PrP (PrP^Sc) but also, partially, mixed type‐2 PrP^Sc. A Japanese woman complained of visual disorder at the age of 86 years and then showed disorientation and memory disturbances. Magnetic resonance imaging (MRI) showed cerebral cortical hyperintensity on diffusion‐weighted images. The patient died 2 months after the onset of symptoms; her condition did not reach the akinetic mutism state and periodic sharp‐wave complexes on electroencephalography and myoclonus were not recognized. The brain weighed 1100 g and neuropathological examination showed extensive fine vacuole‐type spongiform changes in the cerebral cortex. In some cortical regions, large confluent vacuole‐type spongiform changes were also present. Gliosis and hypertrophic astrocytosis were generally mild, and tissue rarefaction of the neuropil and neuronal loss were not apparent. PrP immunostaining showed diffuse synaptic‐type PrP deposition in the cerebral gray matter, but some regions with large confluent vacuoles showed perivacuolar‐type deposition. We speculated, based on the clinicopathological findings and previous reports, that most MM1‐type sporadic CJD cases may be associated with type‐2 PrP^Sc, at least partially, within certain regions of the cerebrum.