Creutzfeldt-Jakob disease

Creutzfeldt-Jakob disease (CJD), a neurodegenerative disorder that is the commonest form of human prion disease or transmissible spongiform encephalopathies (TSEs). Four types of CJD are known: Sporadic (sCJD), familial or genetic (gCJD); iatrogenic (iCJD) and variant CJD (vCJD). The latter results from transmission of bovine spongiform encephalopathy (BSE) from cattle to humans. The combination of PrP(Sc) peptide (either 21 kDa or 19 kDa) and the status of the codon 129 of the gene (PRNP) encoding for PrP (either Methionine or Valine) is used to classify sCJD into 6 types: MM1 and MV1, the most common; VV2; MV2 (Brownell/Oppenheimer syndrome); MM2; VV1 and sporadic fatal insomnia, in that order of prevalence. Genetic CJD is caused by diverse mutations in the PRNP gene. The neuropathology of CJD consists of spongiform change, astro- and microgliosis and poorly defined neuronal loss. In a proportion of cases, amyloid plaques, like those of kuru, are seen. PrP immunohistochemistry reveals different types of PrP(Sc) deposits - the most common is the synaptic-type, but perivacuolar, perineuronal and plaque-like deposits may be also detected.

Non-human primates in prion research

Prion diseases or transmissible spongiform encephalopathies are neurodegenerative disorders affecting a broad range of mammals including humans. Initially thought to be of viral origin, it became apparent that prion diseases are unique transmissible entities where a misfolded, highly stable conformer (PrPSc) of the host encoded prion protein (PrPC) represents an essential component of infectious "prions". Prion diseases are mainly studied in rodents, yet several scientific breakthroughs in prion research can be attributed to prion research in primates. In this review we summarize and discuss how studies in non-human primates have advanced our knowledge on transmissibility, pathophysiology and tissue tropism of prions. We discuss assets of non-human primate and rodent models of prion disease pointing out alternatives to experiments in primates.

Glioma cells showing IDH1 mutation cannot be propagated in standard cell culture conditions

BACKGROUND

It has recently been reported by several sources that original (i.e., present in vivo) glioma cell phenotypes or genotypes cannot be maintained in vitro. For example, glioblastoma cell lines presenting EGFR amplification cannot be established.

METHODS AND RESULTS

IDH1 sequencing and loss of heterozygosity analysis was performed for 15 surgery samples of astrocytoma and early and late passages of cells derived from those and for 11 archival samples. We were not able to culture tumour cells presenting IDH1 mutations originating from currently proceeded 10 tumours; the same results were observed in 7 samples of archival material.

CONCLUSION

The IDH1 mutation is expected to be almost mutually exclusive with EGFR amplification, so glioma cells with IDH1 mutations seem to represent a new group of tumour cells, which cannot be readily analysed in vitro because of their elimination. The reasons for this intriguing phenomenon should be investigated since its understanding can help to define a new therapeutic approach based on simulating in vivo conditions, responsible for tumour cells elimination in vitro. Moreover, a new model for culturing glioma cells in vitro should be designed since the current one does not provide conditions corresponding to in vivo growth.

Autophagy contributes to widespread neuronal degeneration in hamsters infected with the Echigo-1 strain of Creutzfeldt-Jakob disease and mice infected with the Fujisaki strain of Gerstmann-Sträussler-Scheinker (GSS) syndrome

The authors report here robust autophagy observed by electron microscopy in both the Echigo-1 strain of Creutzfeldt-Jakob disease in hamsters and the Fujisaki strain of Gerstmann-Sträussler-Scheinker disease in mice. In both models, autophagic vacuoles were observed in several cellular compartments. In neuronal cell bodies, autophagic vacuoles of different size were seen. The cytoplasm of some neurons also contained semicircular cisterns equivalent to an early autophasophore. The major target of autophagy was dystrophic neurites, i.e., enlarged neuritic processes--mostly dendrites but also axonal terminals and preterminals. They contained numerous double- or multiple-membrane-bound autophagosomes or autophagolysosomes and large multivesicular bodies. Multivesicular bodies were also observed within autophagic vacuoles, and large multivesicular bodies were seen within synaptic terminals. Some dystrophic neurites was filled almost completely with multivesicular bodies; the latter were occasionally confluent. The authors conclude that autophagy is an important part of neuropathology in prion disease. They also suggest that spongiform vacuoles, a hallmark for the whole group of prion diseases, may in reality originate from autophagic vacuoles.

Analysis of the prognostic significance of selected morphological and immunohistochemical markers in ependymomas, with literature review

AIM

Ependymal tumours are relatively uncommon primary neoplasms of the central nervous system. Histological criteria distinguishing ependymoma and anaplastic ependymoma are not clear-cut and other parameters are required to allow more precise prognostication in these tumours. We analysed the histological and immunohistochemical features of these tumours (Ki-67, cyclin D1, EGFR, hTERT, Olig2) and correlated them with the clinical outcome.

MATERIAL AND METHODS

We analysed 39 patients with grade II ependymoma (30) and anaplastic ependymoma (9). Twenty-eight tumours developed in children and the remaining 11 patients were adults with intracranial and intraspinal tumours. Eighteen patients died during the follow-up period.

RESULTS AND CONCLUSIONS

Overall survival was reduced significantly for paediatric patients and patients with intracranial tumour. High-grade tumours, increased mitotic index and increased cellularity had an unfavourable influence on survival. Other histological parameters such as nuclear atypia, necrosis and microvascular proliferation did not alter the survival rate. Increased Ki-67 and cyclin D1 indices correlated with worse prognosis. Furthermore, any level of cyclin D1 expression in WHO grade II ependymomas was strongly associated with higher risk of death. No correlation was identified between Olig2, EGFR and hTERT expression and the outcome of the patients.

Polycomb genes expression as a predictor of poor clinical outcome in children with medulloblastoma

INTRODUCTION

Medulloblastoma is the most frequent type of embryonal tumor in the pediatric population, accounting for 20-25% of all brain tumors in children. Recently, the suspected contribution of the Polycomb group (PcG) genes in medulloblastoma development was described. PcG genes play an important role in developmental processes; they are also involved in the self-renewal of hematopoietic and neural stem cells as well as in malignant transformation.

PURPOSE

In this study, we evaluated the expression of BMI1and PCGF2, members of family of PcG genes, and their potential target, MYC oncogene, and analyzed their association with demographic and clinical data.

MATERIALS AND METHODS

Thirty-one children (18 males and 13 females, aged from 0.4 to 17 years) with medulloblastoma were included in this study. The gene's expression level was measured by quantitative real-time PCR, obtained using the two-color multiplexing technique.

RESULTS

We found that the higher expression levels of BMI1 and PCGF2 genes were associated with significantly decreased patient survival (p = 0.02 and p = 0.012, respectively). Significant differences between gender were found, with a higher expression level of the PCGF2 gene observed among females (p = 0.02).

CONCLUSION

Our analysis showed correlation between BMI1 and PCGF2 gene's expression and survival in children with medulloblastoma.

Glioblastoma-derived spheroid cultures as an experimental model for analysis of EGFR anomalies

Glioblastoma cell cultures in vitro are frequently used for investigations on the biology of tumors or new therapeutic approaches. Recent reports have emphasized the importance of cell culture type for maintenance of tumor original features. Nevertheless, the ability of GBM cells to preserve EGFR overdosage in vitro remains controversial. Our experimental approach was based on quantitative analysis of EGFR gene dosage in vitro both at DNA and mRNA level. Real-time PCR data were verified with a FISH method allowing for a distinction between EGFR amplification and polysomy 7. We demonstrated that EGFR amplification accompanied by EGFRwt overexpression was maintained in spheroids, but these phenomena were gradually lost in adherent culture. We noticed a rapid decrease of EGFR overdosage already at the initial stage of cell culture establishment. In contrast to EGFR amplification, the maintenance of polysomy 7 resulted in EGFR locus gain and stabilization even in long-term adherent culture in serum presence. Surprisingly, the EGFRwt expression pattern did not reflect the latter phenomenon and we observed no overexpression of the tested gene. Moreover, quantitative analysis demonstrated that expression of the truncated variant of receptor—EGFRvIII was preserved in GBM-derived spheroids at a level comparable to the initial tumor tissue. Our findings are especially important in the light of research using glioblastoma culture as the experimental model for testing novel EGFR-targeted therapeutics in vitro, with special emphasis on the most common mutated form of receptor—EGFRvIII.

Imperfect oligodendrocytic and neuronal differentiation of glioblastoma cells

Previously, we have reported that glioblastoma (GBM) cells can be differentiated into cells showing neuronal, glial and non-neural (mesenchymal) phenotypes. Before the differentiation the GBM cells co-expressed GFAP, CD44, Beta III tubulin, MAP2, Vimentin, Nestin and SOX-2, whereas during the exposure to a neural differentiation medium the differentiation process was arrested at the early stages and the GBM cells presented features of four phenotypes: multi-lineage, non-neural (mesenchymal), intermediate of neuronal cells and glial cells. Currently, we decided to check if changes in expression of: TH (tyrosine hydroxylase, marker of catecholaminergic cells) and GABA (neurotransmitter of GABAergic neurons) and markers of oligodendrocytic cells (O4, CNP) occur during the exposure of GBM cells to the differentiation medium. After exposure to the PDGF alpha and thyroid hormones (oligodendrocytic differentiation medium 10-30 days) features of oligodendrocytic differentiation were presented by 0.2-2.4% of analyzed cells. During the prolonged neural differentiation (GDNF, bFGF 20-30 days) only few cells showed expression of GABA. Moreover, in our cell cultures, there were not cells expressing markers of catecholaminergic neurons - TH. Our work confirmed that the neuronal differentiation of GBM was inhibited at the stage of the neuronal intermediate phenotype. Moreover, we showed that the oligodendrocytic differentiation of GBM cells is very inefficient.

Kuru and D. Carleton Gajdusek: a close encounter

Kuru, the first human transmissible spongiform encephalopathy, was transmitted to chimpanzees by D. Carleton Gajdusek (1923-2008). In this review, I briefly summarize the history of this seminal discovery alongside its epidemiology, clinical picture, neuropathology and molecular genetics. The discovery of kuru opened new windows into the realms of human medicine and was instrumental in the later transmission of Creutzfeldt-Jakob disease as well as the prediction that bovine spongiform encephalopathy would be transmitted to humans. It was one of the greatest discoveries in biomedical sciences of the 20th century.

Transmissible mink encephalopathy - review of the etiology of a rare prion disease

We review here the history, neuropathology, clinical picture and molecular data on transmissible mink encephalopathy (TME). This obscure disease is of utmost importance as it is plausible that it represents a transmission of hidden bovine spongiform encephalopathy (BSE) to mink in the USA. Of special interest is the similarity of L-type of BSE and TME. Furthermore, experimental molecular studies showed the TME strain-specific in vitro conversion in a cell-free system. In addition, we show here for the first time confocal laser microscopy studies of co-localization of PrPd- amyloid plaques and GFAP-expressing astrocytes.

Kuru: its ramifications after fifty years

Kuru was the first human neurodegenerative disease in the group of transmissible spongiform encephalopathies, prion diseases or, in the past, slow unconventional virus diseases. It was reported to Western medicine in 1957 by Gajdusek and Zigas. Kuru was spread by endocannibalism and because of this the ratio of affected women and children to men was excessive. The hallmark of kuru neuropathology is the amyloid plaque. We may speculate what would happen if kuru had not been discovered or did not exist. The infectious nature of Creutzfeldt-Jakob disease (CJD) would probably not have been suspected until the beginning of the variant CJD (vCJD) outbreak in the UK. Creutzfeldt-Jakob disease and Gerstmann-Sträussler-Scheinker disease would have remained for decades as obscure neurodegenerations of merely academic interest. The familial forms of CJD would not have benefited from PRNP gene (a gene encoding for prion protein) analysis, but only later would have been studied by linkage analysis and reverse genetics probably. The study of kuru would have probably been of minimal interest to veterinarians and anthropologists until the bovine spongiform encephalopathy (BSE) epidemic began to exert its devastating effect. The discovery of vCJD would have been delayed, as no surveillance would have been initiated for CJD. And perhaps most importantly, the realization of 'protein-misfolding diseases', including not only the neurodegenerative but also an increasing number of non-neurological disorders, would have been delayed by decades.

Pathology and immunocytochemistry of a kuru brain

We report here results of modern staining techniques including anti-prion protein (PrP) immunocytochemistry to a set of archival brain specimens of a 16 year-old male who died from kuru in 1967. Brain suspensions transmitted disease to chimpanzees and New World monkeys. The PrP gene is homozygous for valine at the polymorphic codon 129. Histology shows neuronal loss, spongiform change, and astrogliosis. Lesions are maximal in parasagittal and interhemispheric areas of frontal, central and parietal cortex, cingulate cortex, striatum, and thalamus, and are accentuated in middle and deep cerebral cortical layers. PrP accumulates as diffuse synaptic type deposits and mostly unicentric plaques. PrP deposition is maximal in parasagittal and interhemispheric areas of frontal, central and parietal cortex, cingulate cortex, basal ganglia, and cerebellar cortex. Plaques are prominent in the striatum, thalamus, and granular layer of cerebellar cortex. Meticulous examination reveals only rare "florid" plaques with surrounding vacuolation. We conclude that 1) pathology including immunomorphology of PrP deposition in this kuru brain is within the lesion spectrum of Creutzfeldt-Jakob disease although plaques are unusually prominent and widespread; 2) kuru does not share the neuropathological hallmarks of the new Creutzfeldt-Jakob disease variant recently reported in the UK and France; 3) topographic prominence of PrP deposition parallels that of spongiform change and/or astrogliosis.

BCR expression is decreased in meningiomas showing loss of heterozygosity of 22q within a new minimal deletion region

Neurofibromin 2 (NF2), located on chromosome arm 22q, has been established as a tumor suppressor gene involved in meningioma pathogenesis. In our study, we investigated 149 meningiomas to determine whether there are additional tumor suppressor genes localized on chromosome 22q, apart from NF2, that might be involved in meningioma pathogenesis. The LOH analysis on chromosome 22q identified two regions of deletion: the first one, which is limited to the NF2 gene locus, and the second one, which is outside this location. The new minimal deletion region (MDR) included the following genes: BCR (breakpoint cluster region), RAB36 (a member of RAS oncogene family), GNAZ [guanine nucleotide binding protein (G protein), alpha-z polypeptide], and RTDR1 (rhabdoid tumor deletion region gene 1). The expression levels of all these genes, including NF2, were subsequently analyzed by quantitative real-time polymerase chain reaction. We observed a significantly lowered expression level of NF2 in meningiomas with 22q loss of heterozygosity (LOH) within NF2 region compared to the one in meningiomas with 22q retention of heterozygosity (ROH, P<0.05). Similarly, BCR showed a significantly lowered expression in meningiomas with 22q LOH within the new MDR compared to cases with 22q ROH (P<0.05). Our data, together with the already published information considering BCR function suggest that BCR can be considered as a candidate tumor suppressor gene localized on chromosome 22q which may be involved in meningioma pathogenesis.

Ultrastructural study of florid plaques in variant Creutzfeldt-Jakob disease: a comparison with amyloid plaques in kuru, sporadic Creutzfeldt-Jakob disease and Gerstmann-Sträussler-Scheinker disease

BACKGROUND

Although the histological features of the amyloid plaques in variant Creutzfeldt-Jakob disease (vCJD) are distinct from those in other forms of prion disease [kuru, sporadic Creutzfeldt-Jakob disease (sCJD) and Gerstmann-Sträussler-Scheinker disease (GSS)], their ultrastructural features have only been described in a single case report.

AIMS

To study vCJD plaques systematically and compare them with plaques in kuru, sCJD, GSS and Alzheimer disease (AD).

METHODS

Amyloid plaques were studied by transmission electron microscopy and image analysis in five cases of vCJD, three cases of GSS, two cases of sCJD, one case of kuru and five cases of AD. Immunohistochemistry was performed on paraffin sections from one case of vCJD, two cases of GSS, one case of kuru and two cases of sCJD.

RESULTS

The florid plaques in vCJD were either compact or more diffuse; in both forms, the radiating fibrils were organized into thick 'tongues', in contrast to kuru plaques. Dystrophic neurites (DNs) containing lysosomal electron-dense bodies or vesicles surrounded florid plaques. Microglial cells were found within florid plaques; occasional amyloid fibrils were identified in membrane-bound pockets of microglial cells. In vCJD, there was significant tau immunoreactivity in DNs around florid plaques while, in sCJD, GSS and kuru, minimal tau immunoreactivity was observed around plaques.

CONCLUSIONS

The ultrastructure of the florid plaques and DNs in vCJD is more reminiscent of neuritic plaques in AD than kuru or multicentric plaques. These findings may reflect differences both in the strains of the transmissible agents responsible for these disorders and in host factors.

Elimination of wild-type P53 mRNA in glioblastomas showing heterozygous mutations of P53

We screened 50 glioblastomas for P53 mutations. Five glioblastomas showed heterozygous mutations, while three were putatively heterozygous. Six of these eight glioblastomas showed elimination of wild-type P53 mRNA. These results strongly suggest that some sort of mechanism(s) favouring mutated over wild-type P53 mRNA exists in glioblastoma cells with heterozygous mutations of this gene.

Cell death and autophagy in prion diseases (transmissible spongiform encephalopathies)

Neuronal autophagy, like apoptosis, is one of the mechanisms of programmed cell death. In this review, we summarize current information about autophagy in naturally occurring and experimentally induced scrapie, Creutzfeldt-Jakob disease and Gerstmann-Sträussler-Scheinker syndrome against the broad background of neural degenerations in transmissible spongiform encephalopathies (TSEs). Typically a sequence of events is observed: from a part of the neuronal cytoplasm sequestrated by concentric arrays of double membranes (phagophores); through the enclosure of the cytoplasm and membrane proliferation; to a final transformation of the large area of the cytoplasm into a collection of autophagic vacuoles of different sizes. These autophagic vacuoles form not only in neuronal perikarya but also in neurites and synapses. On the basis of ultrastructural studies, we suggest that autophagy may play a major role in transmissible spongiform encephalopathies and may even participate in the formation of spongiform change.

Subependymal plaques in scrapie-affected hamster brains--why are they so different from compact kuru plaques?

We report here routine thin-section and immunogold electron microscopic studies on diffuse plaques in scrapie-affected hamster brains. These plaques were not discernible by routine HE staining. Ultrastructurally, plaques were recognized as areas of low electron density containing haphazardly-oriented fibrils, but not as stellate compact structures typical of mouse scrapie models; hence we labelled them "loose plaques". Following immunohistochemistry at the electron microscopy level, fibrils within plaques were heavily decorated with PrP-conjugated gold particles. Loose plaques were located beneath the basal border of the ependymal cells and around blood vessels in the adjacent subependymal neuropil. When dystrophic neurites containing electron-dense inclusion bodies, some of them autophagic vacuoles [59], were seen within the plaque perimeter, they always remained PrP-negative. Some microglial cells were observed in close contact with PrP-positive plaques, and secondary lysosomes within these cells were heavily decorated with gold particles.

Prion diseases: a riddle wrapped in a mystery inside an enigma

It is now widely accepted that many structurally diverse proteins can misfold and cause so-called "conformational diseases", including the most common neurodegenerations, Alzheimer's disease and Parkinson's disease. The conversion of largely a-helical or random coil proteins into cross-beta-pleated sheet conformations that form first oligomers and then fibrils underlies these disorders. However, this alpha- to beta-structure transition seems to be a generic propensity of all globular proteins, not only those involved in neurodegenerations, not to mention "prion diseases". Metaphorically, all these neurodegenerations are "infectious" in the sense that misfolded beta-sheeted conformers are formed in a nucleation process in which preformed metastable oligomer acts as a seed (a nucleus) to convert a normal into an abnormal protein. However, in none but transmissible spongiform encephalopathies (TSEs) has infectivity in a microbiological sense ever been observed, and even in TSEs the formation of misfolded protein is not necessarily accompanied by the generation of infectivity de novo. Furthermore, certain "prion diseases" are not TSEs but just "proteinopathies" caused by accumulation of abnormally misfolded PrPd. The presence of a massive amount of PrP-amyloid and no infectivity casts doubts on whether TSEs are really infectious amyloidoses. The misfolding of PrP may yet prove to be an epiphenomenon secondary to infection with a still unknown infectious agent. If, on the other hand, the purely proteinaceous character of the replicating unit of TSE infectivity is ultimately found to be correct, the critical issues become 1) the mechanism by which a misfolded PrP template induces normal protein molecules to adopt the same pathologically misfolded conformation, and 2) the intracellular conditions that are responsible for strain differences in these molecules.

Kuru-fifty years later

Kuru, the first human neurodegenerative disease classified as a transmissible spongiform encephalopathy, prion disease or, in the past, slow unconventional virus disease, was first reported to Western medicine in 1957 by D. Carleton Gajdusek and Vincent Zigas. Thus, this year marks the 50th anniversary of kuru discovery, highlighted by the symposium The end of kuru: 50 years of research into an extraordinary disease organized by John Collinge and Michael Alpers at the Royal Society, London, November 11-12, 2007. In this review, we summarize some data on the epidemiology, neuropathology and clinical picture of kuru.

Phenotype of the DYT1 mutation in the TOR1A gene in a Polish population of patients with dystonia. A preliminary report

BACKGROUND AND PURPOSE

DYT1 dystonia is the most common form of inherited primary dystonia. The aim of the study was: 1) to evaluate the prevalence of the DYT1 mutation in a population of Polish patients with early-onset generalized dystonia and with other forms of familial dystonia, 2) to evaluate the frequency of the DYT1 mutation in patients with writer's cramp, 3) to characterize the phenotype of the DYT1 mutation in the Polish population, and 4) to define the group of patients in whom genetic testing is recommended.

MATERIAL AND METHODS

The following groups of patients were included in the study: 1) patients with early-onset (<30 years) generalized dystonia and those patients with onset after age 30 years who have relatives with early-onset dystonia, 2) patients with writer's cramp (focal or as part of segmental dystonia) independently of age of onset, 3) asymptomatic (adult only) relatives of the diagnosed DYT1 carriers. Genetic tests were performed in 63 subjects---28 sporadic cases of dystonia, 20 patients with familial dystonia, and 15 asymptomatic relatives of patients with confirmed DYT1 mutation.

RESULTS

The DYT1 mutation was found in 17 subjects--10 patients with dystonia and 7 asymptomatic relatives (from 6 families). In all mutation carriers dystonia occurred in one limb before age 26 years. In 8 patients, generalization of dystonia was observed and in 2 cases it remained in a focal form.

CONCLUSIONS

1. The prevalence of DYT1 mutation among patients with early-onset (<or= 24 years) dystonia was 20.8% and it was similar to that found in other European populations. 2. No DYT1 mutation was found among sporadic cases of writer's cramp. 3. In the studied group the most common was the phenotype with early onset (<or= 24 years) and the first symptoms localized in one of the limbs. 4. The obtained results confirm that the recommendations available in the literature concerning DYT1 genetic testing can be applied to the Polish population.

Diverse molecular pattern in a bihemispheric glioblastoma (butterfly glioma) in a 16-year-old boy

Glioblastoma multiforme (GBM), the most common malignant brain tumor of adults, is relatively rare in children. In a GBM affecting a 16-year-old boy, the tumor spread across the corpus callosum (butterfly glioma). This type of bilateral hemispheric growth has previously been thought to result from spread along the white matter tracts. Two samples obtained from opposite sides of the same tumor were analyzed comprehensively for loss of heterozygosity (LOH) and microsatellite instability (MSI). Amplification of EGFR and MDM2 was studied by means of multiplex polymerase chain reaction. Exons 5, 6, 7, and 8 of TP53 were screened for mutations by sequencing. In neither specimen were molecular alterations found in the EGFR, MDM2, or TP53 genes. The specimen obtained from the right hemisphere exhibited a high level of MSI and LOH in chromosome arms 5q, 9p, and 13q. The specimen from the left hemisphere exhibited LOH in chromosome arms 3p, 5q, 9p, 9q, 10p, 10q, and 13q. Here we propose four plausible hypothetical scenarios underlying the tumorigenesis of this GBM.

Disease-specific particles without prion protein in prion diseases - phenomenon or epiphenomenon?

The search for the cause of transmissible spongiform encephalopathies (TSEs) has a long and tortuous history. In a recent paper, 25-nm virus-like particles were identified that were consistently observed in cell cultures infected with Creutzfeldt-Jakob disease (CJD) and scrapie; they are similar to, or even identical with, the virus-like tubulovesicular structures (TVS) found in experimental scrapie as early as in 1968, and subsequently in all naturally occurring and experimentally induced TSEs. These particles have been viewed with caution by the scientific community because of the unverified or uninterpretable record of virus-like structures reported over the years in TSEs. TVS are spherical or tubular particles of approximate diameter 25-37 nm. They are smaller than synaptic vesicles, but larger than many particulate structures of the central nervous system, such as glycogen granules. Their electron density is higher compared with synaptic vesicles, and in experimental murine scrapie, they form paracrystalline arrays. None of these observations distinguish between TVS as an entity critical to the infectious process, or as a highly specific ultrastructural epiphenomenon, but their consistent presence in all TSEs demands further research.

[Significance and prospects of study on molecular alterations in oligodendrogliomas]

Oligodendroglial tumours represent a type of tumours in which molecular alterations may become a significant prognostic factor. During the last decade, enormous progress in understanding of these alterations has been accomplished. Oligodendrogliomas show distinct genetic alterations, allowing us to distinguish them from other types of gliomas. The loss of heterozygosity (LOH) on chromosomes 1p and 19q were reported to be the most frequently observed alterations. While loss of heterozygosity on chromosome 1p is a statistically significant predictor of chemosensitivity, combination with deletions on chromosome 19q was reported to be associated with both chemosensitivity and longer recurrence-free survival after therapy. Conversely, allelic loss on chromosome 10q, observed in many anaplastic oligodendrogliomas, predicts rather poor outcome. The present paper is a compilation of the newest information on the characteristics of the genetic alterations related to the clinical course of oligodendrogliomas, which seems to be important for the proper diagnostics and selection of the appropriate methods of treatment.