Murine scrapie infection causes an abnormal germinal centre reaction in the spleen

Follicular dendritic cells (FDCs) of the lymphoreticular system play a role in the peripheral replication of prion proteins in some transmissible spongiform encephalopathies (TSEs), including experimental murine scrapie models. Disease-specific PrP (PrPd) accumulation occurs in association with the plasmalemma and extracellular space around FDC dendrites, but no specific immunological response has yet been reported in animals affected by TSEs. In the present study, morphology (light microscopical and ultrastructural) of secondary lymphoid follicles of the spleen were examined in mice infected with the ME7 strain of scrapie and in uninfected control mice, with or without immunological stimulation with sheep red blood cells (SRBCs), at 70 days post-inoculation or at the terminal stage of disease (268 days). Scrapie infection was associated with hypertrophy of FDC dendrites, increased retention of electron-dense material at the FDC plasma membrane, and increased maturation and numbers of B lymphocytes within secondary follicles. FDC hypertrophy was particularly conspicuous in immune-stimulated ME7-infected mice. The electron-dense material was associated with PrP Napoli accumulation, as determined by immunogold labelling. We hypothesize that immune system changes are associated with increased immune complex trapping by hypertrophic FDCs expressing PrP Napoli molecules at the plasmalemma of dendrites, and that this process is exaggerated by immune system stimulation. Contrary to previous dogma, these results show that a pathological response within the immune system follows scrapie infection.     

Follicular dendritic cell dedifferentiation reduces scrapie susceptibility following inoculation via the skin

Transmissible spongiform encephalopathies (TSEs) are a group of subacute infectious neurodegenerative diseases that are characterized by the accumulation in affected tissues of PrP(Sc), an abnormal isoform of the host prion protein (PrPc). Following peripheral exposure, TSE infectivity and PrP(Sc) usually accumulate in lymphoid tissues prior to neuroinvasion. Studies in mice have shown that exposure through scarified skin is an effective means of TSE transmission. Following inoculation via the skin, a functional immune system is critical for the transmission of TSEs to the brain, but until now, it has not been known which components of the immune system are required for efficient neuroinvasion. Temporary dedifferentiation of follicular dendritic cells (FDCs) by treatment with an inhibitor of the lymphotoxin-beta receptor signalling pathway (LTbetaR-Ig) 3 days before or 14 days after inoculation via the skin, blocked the early accumulation of PrP(Sc) and TSE infectivity within the draining lymph node. Furthermore, in the temporary absence of FDCs before inoculation, disease susceptibility was reduced and survival time significantly extended. Treatment with LTbetaR-Ig 14 days after TSE inoculation also significantly extended the disease incubation period. However, treatment 42 days after inoculation did not affect disease susceptibility or survival time, suggesting that the infection may have already have spread to the nervous system. Together these data show that FDCs are essential for the accumulation of PrP(Sc) and infectivity within lymphoid tissues and subsequent neuroinvasion following TSE exposure via the skin.     

Follicular dendritic cells as targets for intervention in transmissible spongiform encephalopathies

Transmissible spongiform encephalopathies (TSEs) are often acquired peripherally, for example by ingestion or iatrogenic exposure. After entry, TSE agents, as identified by disease-specific protein accumulation, usually accumulate on follicular dendritic cells (FDCs) in lymphoid tissues long before infection spreads to the brain. Neuroinvasion of TSE agents is significantly impaired in the absence of mature FDCs. Treatments that interfere with the integrity or function of FDCs extend survival time by blocking replication in lymphoid tissues and spread to the brain. The identification of FDCs as critical for TSE pathogenesis provides a cellular target to which therapies can be specifically directed.     

Sites of prion protein accumulation in scrapie-infected mouse spleen revealed by immuno-electron microscopy

Prion protein (PrP) from the brains of animals with transmissible spongiform encephalopathies is partially protease resistant (PrP(res)) compared with fully sensitive PrP (PrP(sen)) from uninfected brains. In most experimental models, PrP(res) is a reliable indicator of infectivity. Light microscopic studies have suggested that both PrP(sen) and disease-specific accumulations of PrP are associated with follicular dendritic cells (FDCs). Using immunogold electron microscopy, this study has demonstrated disease-specific accumulation of PrP in the spleens of C57 BL mice, 70 days after intracerebral infection with the ME7 strain of scrapie and at the terminal stage of disease at 170 days. At both stages, tingible body macrophages contained PrP within lysosomes and PrP was also detected at the plasmalemma of FDCs. In the light zone of follicles of terminally diseased mice, all FDC dendrites were arranged in the form of highly reactive or hyperplastic labyrinthine glomerular complexes, within which PrP was consistently seen between FDC processes in association with abundant electron dense material, interpreted as antigen-antibody complexes. Within some glomeruli, fibrillar forms of PrP consistent with amyloid were seen. At 70 days after challenge, large or hyperplastic labyrinthine complexes were rare and invariably labelled for PrP. However, sparse PrP labelling was also seen on simple FDC processes at this stage. The ubiquitous accumulation of extracellular PrP in complex glomerular dendrites of FDCs in spleens from terminally affected mice, contrasted with simple FDC profiles, sparse PrP and limited electron dense deposits in all but a few FDCs of 70-day post-infected mice. This suggests that FDCs continually release PrP from the cell surface, where it is associated with trapped antigen-antibody complexes and dendritic extension. It is likely that tingible body macrophages acquire PrP following phagocytosis of PrP within iccosomes or from the extracellular space around FDC dendrites. These studies would not support an intracellular phase of PrP accumulation in FDCs but show that PrP is produced in excess by scrapie-infected cells from where it is released into the extracellular space. We suggest that PrP(sen) is involved in dendritic extension or in the process of antibody-antigen trapping, perhaps as part of the binding mechanism for antigen-antibody complexes. Copyright Crown copyright 2000. Reproduced with the permission of Her Majesty's Stationery Office. Published by John Wiley & Sons, Ltd.     

Involvement of clusterin and the aggresome in abnormal protein deposits in myofibrillar myopathies and inclusion body myositis

Myofibrillar myopathies (MM) are characterized morphologically by the presence of non-hyaline structures corresponding to foci of dissolution of myofibrils, and hyaline lesions composed of aggregates of compacted and degraded myofibrillar elements. Inclusion body myositis (IBM) is characterized by the presence of rimmed vacuoles, eosinophilic inclusions in the cytoplasm, rare intranuclear inclusions, and by the accumulation of several abnormal proteins. Recent studies have demonstrated impaired proteasomal expression and activity in MM and IBM, thus accounting, in part, for the abnormal protein accumulation in these diseases. The present study examines other factors involved in protein aggregation in MM and IBM. Clusterin is a multiple-function protein which participates in Abeta-amyloid, PrP(res) and a-synuclein aggregation in Alzheimer disease, prionopathies and a-synucleinopathies, respectively. gamma-Tubulin is present in the centrosome and is an intracellular marker of the aggresome. Moderate or strong clusterin immunoreactivity has been found in association with abnormal protein deposits, as revealed by immunohistochemistry, single and double-labeling immunofluorescence and confocal microscopy, in MM and IBM, and in target structures in denervation atrophy. Gamma-Tubulin has also been observed in association with abnormal protein deposits in MM, IBM, and in target fibers in denervation atrophy. These morphological findings are accompanied by increased expression of clusterin and gamma-tubulin in muscle homogenates of MM and IBM cases, as revealed by gel electrophoresis and Western blots. Together, these observations demonstrate involvement of clusterin in protein aggregates, and increased expression of aggresome markers in association with abnormal protein inclusions in MM and IBM and in targets, as crucial events related to the pathogenesis of abnormal protein accumulation and degradation in these muscular diseases.     

Expression of prion protein in the gut of mice infected orally with the 301V murine strain of the bovine spongiform encephalopathy agent

Transmissible spongiform encephalopathies (TSEs) are characterized by the accumulation of an abnormal, disease-associated prion protein (PrP(d)). Expression of its normal cellular counterpart (PrP(c)) by the host is a pre-requisite for the spread of infection to the central nervous system and the development of disease. Moreover, cells expressing PrP(c) at specific sites such as the gastrointestinal tract might be regarded as the initial point of PrP(c)-PrP(d) conversion after infection by the oral route. In this study, inbred mice of the I/M strain were infected orally with the 301V murine strain of the bovine spongiform encephalopathy agent. The expression of PrP(c) and the accumulation of PrP(d) in the intestine was then investigated immunohistochemically, together with the variations in immunoreactivity that resulted from different pretreatments of the tissue. After proteinase K (PK) pretreatment, abnormal PrP was still detectable only in the gut-associated lymphoid tissue (GALT) of clinically affected mice and, to a much more limited degree, in the enteric nervous system (ENS). Cellular PrP that disappeared after PK treatment was particularly conspicuous in the ENS and present to a lesser extent in the GALT of all mice examined after inoculation with 301V or with normal brain homogenates, as well as in uninoculated controls. These findings suggested that not all PrP found in infected mice was PrP(d) and that part of the PrP(d) was sensitive to PK treatment. Reactivity to PrP antibody 1A8 was consistently found in the absorptive epithelium of the intestinal villi, with or without PK pretreatment. However, epithelial immunolabelling was comparable in inoculated and uninoculated mice and was also consistently seen in PrP "knockout" mice used as controls. It is therefore concluded that immunohistochemically detectable accumulation of PrP(d) in the gut of mice is a relatively late event in the pathogenesis of experimental infection in this model and that the immunoreactivity observed in the intestinal epithelium does not correspond to PrP expression. While enterocytes may still play a role in the uptake of infection from the intestinal lumen, the results do not suggest that these cells are a site of initial accumulation of PrP(d).     

Retinal cell types are differentially affected in sheep with scrapie

Transmissible spongiform encephalopathies (TSEs) are a group of fatal neurodegenerative diseases characterized microscopically by spongiform lesions (vacuolation) in the neuropil, neuronal loss, and gliosis. Accumulation of the abnormal form of the prion protein (PrP(Sc)) has been demonstrated in the retina of natural and non-natural TSE-affected hosts, with or without evidence of microscopically detectable retinal pathology. This study was conducted to investigate the effect of PrP(Sc) accumulation on retinal neurons in a natural host lacking overt microscopical evidence of retinal degeneration by comparing the distribution of retinal cell type-specific markers in control and scrapie-affected sheep. In retinas with PrP(Sc)-immunoreactivity, there was disruption of the normal immunoreactivity patterns of the alpha isoform of protein kinase C (PKCalpha) and vesicular glutamate transporter 1 (VGLUT1), markers of retinal bipolar cells. Altered immunoreactivity was also observed for microtubule-associated protein 2 (MAP2), a marker of a subset of retinal ganglion cells, and glutamine synthetase (GS), a marker of Müller glia. These results demonstrate alterations of immunoreactivity patterns for proteins associated with specific cell types in retinas with PrP(Sc) accumulation, despite an absence of microscopical evidence of retinal degeneration.     

Role of the draining lymph node in scrapie agent transmission from the skin

Transmissible spongiform encephalopathies (TSEs) are neurodegenerative diseases that affect humans and animals. Diseases include scrapie in sheep and Creutzfeldt-Jakob disease in humans. Following peripheral exposure, TSE agents usually accumulate on follicular dendritic cells (FDCs) in lymphoid tissues before neuroinvasion. Studies in mice have shown that TSE exposure through scarified skin is an effective means of transmission. Following inoculation by this route TSE agent accumulation upon FDCs is likewise essential for the subsequent transmission of disease to the brain. However, which lymphoid tissues are crucial for TSE pathogenesis following inoculation via the skin was not known. Mice were therefore created that lacked the draining inguinal lymph node (ILN), but had functional FDCs in remaining lymphoid tissues such as the spleen. These mice were inoculated with the scrapie agent by skin scarification to allow the role of draining ILN in scrapie pathogenesis to be determined. We show that following inoculation with the scrapie agent by skin scarification, disease susceptibility was dramatically reduced in mice lacking the draining ILN. These data demonstrate that following inoculation by skin scarification, scrapie agent accumulation upon FDCs in the draining lymph node is critical for the efficient transmission of disease to the brain.     

The sequential development of abnormal prion protein accumulation in mice with Creutzfeldt-Jakob disease.

The distribution and sequential development of prion protein (PrP) accumulation in the central nervous system (CNS) and non-neuronal organs of mice infected with Creutzfeldt-Jakob disease (CJD) were investigated immunohistochemically using a new pretreatment method that greatly enhanced the immunoreactivity of PrP. Prion protein accumulation in the CNS was first detected at 30 days after inoculation and then developed near the inoculation site or periventricular area, and later spread to the whole cerebrum and then to the pons. Its staining took some characteristic forms. Among non-neuronal organs, PrP accumulated in the follicular dendritic cells (FDCs) in spleen, lymph node, Peyer's patch, and thymus. FDCs staining appeared in spleen, lymph node, and Peyer's patch at 21 or 30 days after inoculation, and in thymus at 90 days. Germinal centers developed in the thymus of some CJD-infected mice. No PrP staining was detected in any examined organs of age-matched control mice.     

Interaction between dendritic cells and nerve fibres in lymphoid organs after oral scrapie exposure

In transmissible spongiform encephalopathies (TSEs), the infectious agent, called PrPsc, an abnormal isoform of the cellular prion protein, accumulates and replicates in lymphoid organs before affecting the nervous system. To clarify the cellular requirements for the neuroinvasion of the scrapie agent from the lymphoid organs to the central nervous system, we have studied, by confocal microscopy, the innervations within Peyer’s patches, mesenteric lymph nodes and the spleen of mice in physiological conditions and after oral exposure to prion. Contacts between nerve fibres and PrPsc-associated cells, dendritic cells (DCs) and follicular dendritic cells (FDCs), were evaluated in preclinical prion-infected mice. Using a double immunolabelling strategy, we demonstrated the lack of innervation of PrPsc-accumulating cells (FDCs). Contacts between nerve fibers and PrPsc-propagating cells (DCs) were detected in T-cell zones and cell-trafficking areas. This supports, for the first time, the possible implication of dendritic cells in the prion neuroinvasion process.     

Dysplastic follicular dendritic cells in hyaline‐vascular Castleman disease: a rare occurrence creating diagnostic difficulty

Follicular dendritic cell (FDC) proliferations and dysplastic FDCs can be seen in Hyaline‐vascular Castleman disease (HVCD). The association between HVCD and FDC sarcoma is well‐documented; dysplastic FDCs may be precursors to FDC sarcoma. Herein, we describe a case of HVCD with strikingly large and dysplastic FDCs, which raised the differential of Hodgkin lymphoma and other neoplasms. Scattered dysplastic FDCs were predominantly in germinal centers and mantle zones, and rarely in interfollicular areas. Although occasional germinal centers contained increased FDCs, no mass forming proliferations were present to suggest FDC sarcoma. Immunostaining demonstrated that the atypical FDCs expressed CD21, clusterin and CXCL13, but not CD23, S100, pankeratin or CD30; they aberrantly expressed epidermal growth factor receptor (EGFR). The present case demonstrates that dysplastic FDCs may be present as isolated cells that require immunophenotyping to distinguish them from malignant entities with similar morphologic features. A variety of FDC markers is required to confirm their origin as the expression of any single marker is not assured, as occurred in this case. Pathologists need be aware of FDC proliferations in HVCD because of their association with FDC sarcoma. Aberrant EGFR expression by dysplastic FDCs may indicate that they are pre‐neoplastic and necessitate long‐term patient follow‐up.     

Preclinical diagnosis of scrapie by immunohistochemistry of third eyelid lymphoid tissue

Ovine scrapie is a member of the transmissible spongiform encephalopathies (TSEs), a heterogeneous family of fatal neurologic disorders characterized by deposition of an abnormal isoform (prion protein [PrP] PrP-Sc) of a cellular sialoglycoprotein in neural tissue. PrP-Sc is detectable in some lymphoid tissues of infected sheep months or years before development of clinical disease. Detection of PrP-Sc in these tissues is the basis for live-animal testing. In this study, we characterize the performance of a preclinical diagnostic test for ovine scrapie based on a monoclonal antibody (MAb)-based immunohistochemistry assay of nictitating membrane ("third eyelid")-associated lymphoid tissue. The results of third eyelid immunohistochemistry assay agreed with the scrapie status of the sheep for 41 of 42 clinical suspects with confirmed scrapie and 174 of 175 sheep without scrapie. Third eyelid sampling agreed with the scrapie status for 36 of 41 clinically normal sheep positive for PrP-Sc immunostaining of brain tissue, including 27 sheep with positive biopsy specimens that progressed to clinical disease with confirmed scrapie 3 to 20 months after biopsy. The assay used MAb F89/160.1.5, which binds to residues 142 to 145 of ovine PrP. This antibody can be used in combination with MAb F99/97. 6.1, which binds to residues 220 to 225. One or both MAbs in this cocktail recognize PrP sequences conserved in most mammalian species in which natural TSEs have been reported. Immunohistochemistry assay of routinely formalin-fixed lymphoid tissues with a cocktail of pan-specific MAbs is a practical, readily standardized live-animal and preclinical test for ovine scrapie.     

Clusterin in bovine spongiform encephalopathy (BSE).

Clusterin mRNA, detected in increased quantities in the cervical spinal cord of cattle with bovine spongiform encephalopathy (BSE), was localized mainly in the neuroglia (including astrocytes) of the lateral and ventral areas of white matter. Axonal degeneration was also observed in these areas. The dorsal horns of the spinal cord in which BSE prion protein (PrP(BSE)) was deposited did not exhibit strong clusterin "up-regulation" but showed increased clusterin immunolabelling with a punctate distribution in the neuropil. Labelling of adjacent sections of the grey matter in BSE-affected spinal cord and thalamus demonstrated that the clusterin was deposited in association with extracellular PrP(BSE).     

Newly discovered forms of prion diseases in ruminants

Transmissible spongiform encephalopathies (TSEs), are fatal neurodegenerative diseases caused by unconventional agents, the prions. They are characterised by the accumulation in infected tissues of an abnormally folded form of the host-encoded prion protein (PrP). This pathological form is partially resistant to protease digestion, leading to the production of so-called PrP(res) fragments. Different isolates from the same host species may show different eletrophoretic profiles, reflecting the existence of different prion strains. The active surveillance of ruminant TSEs implemented in European countries, based on a large-scale biochemical testing of brain tissue samples from carcasses, has revealed PrP(res) profiles unnoticed so far. Experimental transmission of these atypical cases to various transgenic mouse lines has led to the recognition of a novel scrapie strain in sheep and goats, called Nor98, and of two variant strains of spongiform encephalopathy in cattle. This review is aimed at summarising the current knowledge on these newly recognised forms of ruminants TSEs, and at discussing their possible origin and potential implications in terms of animal and human health.     

Ovine infection with the agents of scrapie (CH1641 isolate) and bovine spongiform encephalopathy: immunochemical similarities can be resolved by immunohistochemistry

Immunochemical ("rapid") tests, which recognize a partly protease-resistant conformer of the prion protein (PrP(res)) are now widely used in Europe for the diagnosis of transmissible spongiform encephalopathies (TSEs). Some of these tests can be used to distinguish natural scrapie from experimental bovine spongiform encephalopathy (BSE) in sheep, on the basis of migration pattern differences of PrP(res) in Western immunoblots. However, PrP(res) from sheep inoculated with CH1641 scrapie gives an immunoblot profile similar to that of sheep inoculated with BSE. Therefore, field scrapie strains similar to CH1641 might be misclassified as ovine BSE in the rapid tests currently employed. This study confirmed that the Western blot similarities (size of the unglycosylated band and distinct reactivity with 6H4 and P4 antibodies) between CH1641 and BSE remained consistent regardless of the PrP genotype of the sheep, but the two infections resulted in accumulation of disease-associated PrP (PrP(d)) that could easily be distinguished by the immunohistochemical "peptide mapping" method. This method, which reveals conformational differences of PrP(d) by the use of a panel of antibodies, indicated that PrP(d) from the CH1641 isolate was truncated further upstream in the N terminus than was PrP(d) from other ovine TSEs, including experimental BSE. In addition, the immunohistochemical "PrP(d) profile method", which defines the phenotype of PrP(d) accumulation in the brain of affected sheep, showed that CH1641 infection leads to much more intra-neuronal and considerably less extracellular PrP(d) than does experimental BSE. The overall results demonstrate that a combined Western blotting and immunohistochemical approach is required to discriminate between different TSE strains in sheep.     

Molecular interaction between prion protein and GFAP both in native and recombinant forms in vitro

Gliosis of glial fibrillary acidic protein (GFAP) associated astrocytes is considered to be one of the hallmarks of transmissible spongiform encephalopathies (TSEs). In the present study, remarkable GFAP-PrP(Sc) or GFAP-PrP(C) complexes were separately detected in the brain homogenates of 263 K (Scrapie)-infected or normal hamsters by co-immunoprecipitation assay. To get more exact molecular evidences for interaction between prion protein (PrP) and GFAP, various recombinant PrP or GFAP proteins were expressed using prokaryotic-expressing and in vitro translation system. Using pull down and co-immunoprecipitation assays, reliable molecular interaction between PrP and GFAP was observed, and proteinase K (PK)-digested PrP(Sc) molecules were confirmed to be able to bind the recombinant GFAP specifically as well. The region within PrP that was responsible for interaction with GFAP was narrowed to PK-resistant core of PrP (i.e. aa 91-230). The study of the association of PrP with GFAP supplies the molecular evidence for the observation of co-localization of PrP(Sc) and GFAP in the brains of TSEs and may further provide insight into a potential role of GFAP in the biological function of PrP and the pathogenesis of prion diseases.     

Identification of CXCL13 as a new marker for follicular dendritic cell sarcoma

The homeostatic chemokine CXCL13 is preferentially produced in B-follicles and is crucial in the lymphoid organ development by attracting B-lymphocytes that express its selective receptor CXCR5. Follicular dendritic cells (FDCs) have been identified as the main cellular source of this chemokine in lymphoid organs. Recently, genome-wide approaches have suggested follicular CD4 T-helper cells (T(H)F) as additional CXCL13 producers in the germinal centre and the neoplastic counterpart of T(H)F (CD4+ tumour T-cells in angioimmunoblastic T-cell lymphoma) retains the capability of producing this chemokine. In contrast, no data are available on CXCL13 expression on FDC sarcoma (FDC-S) cells. By using multiple approaches, we investigated the expression of CXCL13 at mRNA and protein level in reactive and neoplastic FDCs. In reactive lymph nodes and tonsils, CXCL13 protein is mainly expressed by a subset of FDCs in B-cell follicles. CXCL13 is maintained during FDC transformation, since both dysplastic FDCs from 13 cases of Castleman's disease and neoplastic FDCs from ten cases of FDC-S strongly and diffusely express this chemokine. This observation was confirmed at mRNA level by using RT-PCR and in situ hybridization. Of note, no CXCL13 reactivity was observed in a cohort of epithelial and mesenchymal neoplasms potentially mimicking FDC-S. FDC-S are commonly associated with a dense intratumoural inflammatory infiltrate and immunohistochemistry showed that these lymphocytes express the CXCL13 receptor CXCR5 and are mainly of mantle zone B-cell derivation (IgD+ and TCL1+). In conclusion, this study demonstrates that CXCL13 is produced by dysplastic and neoplastic FDCs and can be instrumental in recruiting intratumoural CXCR5+ lymphocytes. In addition to the potential biological relevance of this expression, the use of reagents directed against CXCL13 can be useful to properly identify the origin of spindle cell and epithelioid neoplasms.     

Involvement of myeloid dendritic cells in the development of gastric secondary lymphoid follicles in Helicobacter pylori-infected neonatally thymectomized BALB/c mice

We previously described an animal model of Helicobacter pylori-induced follicular gastritis in neonatally thymectomized (nTx) mice. However, it is still not clear whether antigen-presenting dendritic cells (DCs) in the stomach have a role in the development of secondary follicles in H. pylori-infected nTx mice. We investigated the distribution of DC subsets using this model and examined their roles. To identify lymphoid and myeloid DCs, sections were stained with anti-CD11c (pan-DC marker) in combination with anti-CD8alpha (lymphoid DC marker) or anti-CD11b (myeloid DC marker) and were examined with a confocal microscope. Expression of macrophage inflammatory protein 3alpha (MIP-3alpha), which chemoattracts immature DCs, was analyzed by real-time PCR and immunohistochemistry. Follicular dendritic cells (FDCs) were stained with anti-SKY28 antibodies. In noninfected nTx mice, a few myeloid and lymphoid DCs were observed in the bottom portion of the lamina propria, whereas in H. pylori-infected nTx mice, there was an increased influx of myeloid DCs throughout the lamina propria. FDC staining was also observed in the stomachs of members of the infected group. MIP-3alpha gene expression was upregulated in the infected nTx group, and the immunohistochemistry analysis revealed MIP-3alpha-positive epithelial cells. These data suggest that H. pylori infection upregulates MIP-3alpha gene expression in gastric epithelial cells and induces an influx of myeloid DCs in the lamina propria of the gastric mucosa in nTx mice. Myeloid DCs and FDCs might contribute to the development of gastric secondary lymphoid follicles in H. pylori-infected nTx mice.     

Strain-associated variations in abnormal PrP trafficking of sheep scrapie

Prion diseases are associated with the accumulation of an abnormal form of the host-coded prion protein (PrP). It is postulated that different tertiary or quaternary structures of infectious PrP provide the information necessary to code for strain properties. We show here that different light microscopic types of abnormal PrP (PrP^d) accumulation found in each of 10 sheep scrapie cases correspond ultrastructurally with abnormal endocytosis, increased endo-lysosomes, microfolding of plasma membranes, extracellular PrP^d release and intercellular PrP^d transfer of neurons and/or glia. The same accumulation patterns of PrP^d and associated subcellular lesions were present in each of two scrapie strains present, but they were present in different proportions. The observations suggest that different trafficking pathways of PrP^d are influenced by strain and cell type and that a single prion strain causes several PrP^d–protein interactions at the cell membrane. These results imply that strains may contain or result in production of multiple isoforms of PrP^d.     

Prion protein deposition and abnormal synaptic protein expression in the cerebellum in Creutzfeldt-Jakob disease

Prion protein (PrP(C)) is a cell membrane-anchored glycoprotein, which is replaced by a pathogenic protease-resistant, beta-sheet-containing isoform (PrP(CJD) or PrP(SC)) in human and animal prion encephalopathies, including sporadic Creutzfeldt-Jakob disease. Cell fractionation methods show that PrP(C) localizes in presynaptic membrane-enriched fractions. Following infection, abnormal PrP accumulates in nerve cell processes and synaptic regions. The present study examines the possible correlation between abnormal PrP deposition and the expression of synaptic proteins controlling neurotransmission in the cerebellum of six 129 Met/Met sporadic cases of Creutzfeldt-Jakob disease. Aggregates of protease-resistant PrP-positive granules, reminiscent of cerebellar glomeruli, were found in the granular cell layer, whereas fine punctate PrP-immunoreactive deposits occurred in the molecular layer. Small numbers of diffuse, irregular plaque-like PrP deposits in the molecular and granular cell layers were present in every case. The somas of Purkinje cells, and stellate, basket and Golgi neurons, were not immunostained. PrP-immunoreactive fibres were found in the album of the cerebellum and hilus of the dentate nucleus. Punctate PrP deposition decorated the neuropil of the dentate nucleus and the surface of dentate neurons. Synaptic protein expression was examined with synaptophysin, synapsin-1, synaptosomal-associated protein of 25,000 mol. wt, syntaxin-1 and Rab3a immunohistochemistry. Reduced synaptophysin, synapsin-1, synaptosomal-associated protein of 25,000 mol. wt, syntaxin-1 and Rab3a immunoreactivity was noted in the granular cell layer in every case, but reduced expression was inconstant in the molecular layer. Synaptophysin accumulated in axon torpedoes, thus indicating abnormal axon transport. Expression of synaptic proteins was relatively preserved in the dentate nucleus, although synaptophysin immunohistochemistry disclosed large coarse pericellular terminals in Creutzfeldt-Jakob disease, instead of the fine granular terminals in control cases, around the soma of dentate neurons. Finally, Rab3a accumulated in the cytoplasm of Purkinje cells, thus suggesting major anomalies in Rab3a transport.These observations demonstrate, for the first time, abnormal expression of crucial synaptic proteins in the cerebellum of cases with Creutzfeldt-Jakob disease. However, abnormal PrP deposition is not proportional to the degree of reduction of synaptic protein expression in the different layers of the cerebellar cortex and in the dentate nucleus. Therefore, it remains to be elucidated how abnormal PrP impacts on the metabolism of proteins linked to exocytosis and neurotransmission, and how abnormal PrP deposition results in eventual synaptic loss.