132 research outputs found
The synaptic pathology of α-synuclein aggregation in dementia with Lewy bodies, Parkinsonâs disease and Parkinsonâs disease dementia
Parkinsonâs disease (PD) and dementia with Lewy bodies (DLB) are usually associated with loss of dopaminergic neurons. Loss of substantia nigra neurons and presence of Lewy body inclusions in some of the remaining neurons are the hallmark pathology seen in the final stages of the disease. Attempts to correlate Lewy body pathology to either cell death or severity of clinical symptoms, however, have not been successful. While the pathophysiology of the neurodegenerative process can hardly be explained by Lewy bodies, the clinical symptoms do indicate a degenerative process located at the presynapse resulting in a neurotransmitter deficiency. Recently it was shown that 90% or even more of α-synuclein aggregates in DLB cases were located at the presynapses in the form of very small deposits. In parallel, dendritic spines are retracted, whereas the presynapses are relatively preserved, suggesting a neurotransmitter deprivation. The same α-synuclein pathology can be demonstrated for PD. These findings give rise to the notion that not cell death but rather α-synuclein aggregate-related synaptic dysfunction causes the neurodegeneration. This opens new perspectives for understanding PD and DLB. If presynaptic α-synuclein aggregation, not neuronal loss, is the key issue of the neurodegenerative process, then PD and DLB may eventually be treatable in the future. The disease may progress via trans-synaptical spread, suggesting that stem cell transplants are of limited use. Future therapies may focus on the regeneration of synapses
Prion type 2 selection in sporadic Creutzfeldt-Jakob disease affecting peripheral ganglia
In sporadic CreutzfeldtâJakob disease (sCJD), the pathological changes appear to be restricted to the central nervous system. Only involvement of the trigeminal ganglion is widely accepted. The present study systematically examined the involvement of peripheral ganglia in sCJD utilizing the currently most sensitive technique for detecting prions in tissue morphologically. The trigeminal, nodose, stellate, and celiac ganglia, as well as ganglia of the cervical, thoracic and lumbar sympathetic trunk of 40 patients were analyzed with the paraffin-embedded tissue (PET)-blot method. Apart from the trigeminal ganglion, which contained protein aggregates in five of 19 prion type 1 patients, evidence of prion protein aggregation was only found in patients associated with type 2 prions. With the PET-blot, aggregates of prion protein type 2 were found in all trigeminal (17/17), in some nodose (5 of 7) and thoracic (3 of 6) ganglia, as well as in a few celiac (4 of 19) and lumbar (1 of 5) ganglia of sCJD patients. Whereas aggregates of both prion types may spread to dorsal root ganglia, more CNS-distant ganglia seem to be only involved in patients accumulating prion type 2. Whether the prion type association is due to selection by prion type-dependent replication, or due to a prion type-dependent property of axonal spread remains to be resolved in further studies
Upregulation of miRNA hsa-miR-342-3p in experimental and idiopathic prion disease
The aim of our study was to analyze the differential expression of miRNAs in the brains of BSE-infected cynomolgus macaques as a model for Creutzfeldt-Jakob disease (CJD). MicroRNAs (miRNAs) are small noncoding RNAs regulating gene expression by mRNA targeting. Among other functions they contribute to neuronal development and survival. Recently, the lack of miRNA processing has been shown to promote neurodegeneration and deregulation of several miRNAs has been reported to be associated with Scrapie in mice. Therefore, we hypothesized that miRNAs are also regulated in response to human prion disease. We have applied miRNA-microarrays to identify deregulated miRNA candidates in brains of BSE-infected macaques. Shock-frozen brain sections of six BSE-infected and five non-infected macaques were used to validate regulated miRNA candidates by two independent qRT-PCR-based methods. Our study revealed significant upregulation of hsa-miR-342-3p and hsa-miR-494 in the brains of BSE-infected macaques compared to non-infected animals. In a pilot study we could show that hsa-miR-342-3p was also upregulated in brain samples of human type 1 and type 2 sporadic CJD. With respect to the reported regulation of this miRNA in Scrapie-infected mice, we propose that upregulation of hsa-miR-342-3p may be a general phenomenon in late stage prion disease and might be used as a novel marker for animal and human TSEs
Development of an Enzyme-Linked Immunosorbent Assay (ELISA) for the Quantification of ARID1A in Tissue Lysates
ARID1A is a subunit of the mammalian SWI/SNF complex, which is thought to regulate
gene expression through restructuring chromatin structures. Its gene ARID1A is frequently mutated
and ARID1A levels are lowered in several human cancers, especially gynecologic ones. A functional
ARID1A loss may have prognostic or predictive value in terms of therapeutic strategies but has not
been proposed based on a quantitative method. Hardly any literature is available on ARID1A levels in
tumor samples. We developed an indirect enzyme-linked immunosorbent assay (ELISA) for ARID1A
based on the current EMA and FDA criteria. We demonstrated that our ELISA provides the objective,
accurate, and precise quantification of ARID1A concentrations in recombinant protein solutions, cell
culture standards, and tissue lysates of tumors. A standard curve analysis yielded a âgoodness of
fitâ of R2 = 0.99. Standards measured on several plates and days achieved an inter-assay accuracy of
90.26% and an inter-assay precision with a coefficient of variation of 4.53%. When tumor lysates were
prepared and measured multiple times, our method had an inter-assay precision with a coefficient of
variation of 11.78%. We believe that our suggested method ensures a high reproducibility and can
be used for a high sample throughput to determine the ARID1A concentration in different tumor
entities. The application of our ELISA on various tumor and control tissues will allow us to explore
whether quantitative ARID1A measurements in tumor samples are of predictive value
Intracranial Intracerebral Schwannoma: a Case Report and Review of the Literature
Intracranial schwannomas are relatively uncommon, accounting for approximately 8% of all intracranial tumors, while
intracerebral schwannomas represent an even rarer entity, responsible for roughly 1% of all intracranial schwannomas.
After reviewing the relevant literature, we discussed the clinical journey of a 74-year-old woman who presented with a
3-week history of dizziness and nausea. Magnetic resonance imaging revealed a right temporal mass lesion with perifocal
edema. The initial suspicion was the diagnosis of a glioblastoma or metastasis, prompting surgical intervention. During
the surgery, a gross total resection of a noninvasive tumor was successfully performed. The patientâs postoperative
recovery was uneventful. Histopathological examination and confrmatory immunohistochemistry played a crucial role
in reaching the fnal diagnosis of an intracerebral temporal schwannoma, highlighting the diagnostic challenges posed
by radiologically indistinguishable features from metastasis and gliomas. Despite these challenges, complete surgical
removal remains the most preferred treatment option, resulting in a favorable long-term prognosis without the need for
adjuvant or neoadjuvant chemotherapy. Intracerebral schwannomas are exceedingly rare brain tumors, often found on
the brainâs surface or adjacent ventricles. Early and accurate diagnosis can be challenging due to radiological features
overlapping with other intracranial pathologies. Nonetheless, histopathological examination and immunohistochemistry
remain indispensable tools in establishing a defnitive diagnosis and guiding efective treatment strategies. With complete
surgical excision, patients with intracerebral schwannomas can expect a positive outcome and a promising long-term
prognosis. Further research and case studies are warranted to enhance our understanding of these rare tumors and
improve patient outcomes
Hereditary Human Prion Diseases: an Update
Prion diseases in humans are neurodegenerative diseases which are caused by an accumulation of abnormal, misfolded cellular prion protein known as scrapie prion protein (PrPSc). Genetic, acquired, or spontaneous (sporadic) forms are known. Pathogenic mutations in the human prion protein gene (PRNP) have been identified in 10-15 % of CJD patients. These mutations may be single point mutations, STOP codon mutations, or insertions or deletions of octapeptide repeats. Some non-coding mutations and new mutations in the PrP gene have been identified without clear evidence for their pathogenic significance. In the present review, we provide an updated overview of PRNP mutations, which have been documented in the literature until now, describe the change in the DNA, the family history, the pathogenicity, and the number of described cases, which has not been published in this complexity before. We also provide a description of each genetic prion disease type, present characteristic histopathological features, and the PrPSc isoform expression pattern of various familial/genetic prion diseases
MicroRNA 200a as a histologically independent marker for meningioma recurrence : Results of a four microRNA panel analysis in meningiomas
Introduction: Meningiomas are mostly benign neoplasms of the central nervous system. Nevertheless there are recurrences in about 20% after surgical resection. Previous studies could reveal several predictors of meningioma recurrence.
Tumor progression often is associated with a specific pattern of chromosome
losses. Our study investigated the potential function of selected microRNAs as
markers of tumor progression.
Methods: By real-time polymerase chain reaction the expressions of microRNA
21-3p, 34a-3p, 200a-3p, and 409-3p were analyzed in solid tumor and in blood
samples of 51 meningioma patients as well as in blood samples of 20 healthy
individuals. Additionally, aberrations of parts of chromosomes 1, 14, 18, and 22
were analyzed by FISH. Tumor and blood samples were statistically analyzed,
using Spearman's rank correlation coefficient as well as MannâWhitney U- and
KruskalâWallis-Test.
Results: MicroRNA 200a showed significantly lower expressions in recurrent
meningiomas than in newly diagnosed ones. MicroRNA 409 in meningiomas
was correlated significantly with tumor volume and showed a significant negative correlation with patient age. Significance was found between the expression
patterns of microRNAs 34a and 200a with the respective aberrations of chromosome 1p and the microRNA 409 with aberration of chromosome 14. In the male
cohort the expression of microRNA 200a in blood was significantly upregulated
in patients compared to healthy volunteers. By our research the function of microRNA 200a was proved to detect meningioma patients by liquid biopsy.
Conclusion: We detected microRNA 200a as a new biomarker to indicate meningioma recurrences. Future transferability to blood could be important for patient follow-up
PrPSc spreading patterns in the brain of sheep linked to different prion types
Scrapie in sheep and goats has been known for more than 250 years and belongs nowadays to the so-called prion diseases that also include e.g. bovine spongiform encephalopathy in cattle (BSE) and Creutzfeldt-Jakob disease in humans. According to the prion hypothesis, the pathological isoform (PrPSc) of the cellular prion protein (PrPc) comprises the essential, if not exclusive, component of the transmissible agent. Currently, two types of scrapie disease are known - classical and atypical/Nor98 scrapie. In the present study we examine 24 cases of classical and 25 cases of atypical/Nor98 scrapie with the sensitive PET blot method and validate the results with conventional immunohistochemistry. The sequential detection of PrPSc aggregates in the CNS of classical scrapie sheep implies that after neuroinvasion a spread from spinal cord and obex to the cerebellum, diencephalon and frontal cortex via the rostral brainstem takes place. We categorize the spread of PrPSc into four stages: the CNS entry stage, the brainstem stage, the cruciate sulcus stage and finally the basal ganglia stage. Such a sequential development of PrPSc was not detectable upon analysis of the present atypical/Nor98 scrapie cases. PrPSc distribution in one case of atypical/Nor98 scrapie in a presumably early disease phase suggests that the spread of PrPSc aggregates starts in the di- or telencephalon. In addition to the spontaneous generation of PrPSc, an uptake of the infectious agent into the brain, that bypasses the brainstem and starts its accumulation in the thalamus, needs to be taken into consideration for atypical/Nor98 scrapie
Neuropathology in COVID-19 autopsies is defined by microglial activation and lesions of the white matter with emphasis in cerebellar and brain stem areas
IntroductionThis study aimed to investigate microglial and macrophage activation in 17 patients who died in the context of a COVID-19 infection in 2020 and 2021.MethodsThrough immunohistochemical analysis, the lysosomal marker CD68 was used to detect diffuse parenchymal microglial activity, pronounced perivascular macrophage activation and macrophage clusters. COVID-19 patients were compared to control patients and grouped regarding clinical aspects. Detection of viral proteins was attempted in different regions through multiple commercially available antibodies.ResultsMicroglial and macrophage activation was most pronounced in the white matter with emphasis in brain stem and cerebellar areas. Analysis of lesion patterns yielded no correlation between disease severity and neuropathological changes. Occurrence of macrophage clusters could not be associated with a severe course of disease or preconditions but represent a more advanced stage of microglial and macrophage activation. Severe neuropathological changes in COVID-19 were comparable to severe Influenza. Hypoxic damage was not a confounder to the described neuropathology. The macrophage/microglia reaction was less pronounced in post COVID-19 patients, but detectable i.e. in the brain stem. Commercially available antibodies for detection of SARS-CoV-2 virus material in immunohistochemistry yielded no specific signal over controls.ConclusionThe presented microglial and macrophage activation might be an explanation for the long COVID syndrome
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