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1.
Interleukin-1α-immunoreactive (IL-1α+) microglia are prominent components of neuritic plaques in Alzheimer's disease, and may be important in the evolution of neuritic plaques from diffuse amyloid deposits. Neuritic plaques show a characteristic distribution across cerebral regions and are absent in the cerebellum of patients with Alzheimer's disease. We used single- and dual-immunohistochemical labelling to investigate the possibility that the expression of IL-1α is correlated with this regional distribution of neuritic (tau 2-immunoreactive, tau 2+) plaques. In Alzheimer's disease, tau 2+ neuritic plaques occurred with increasing frequency in grey matter of frontal and occipital lobes, temporal lobe, and hippocampus. There were positive correlations between the regional patterns of distribution of activated IL-1α+ microglia and tau2+ neuritic plaques as well as between activated IL-1α+ microglia and activated astrocytes. No activated IL-1α+ microglia, tau 2+ neuritic plaques, or activated astrocyies were observed in cerebellum of these Alzheimer patients. These regional relationships between activated IL-1α+ microglia, tau 2+ neuritic plaques, and activated astrocytes, together with the established functions of IL-1, support a causal association between the overexpression of IL-1 and the evolution of β-amyloid deposits into neuritic plaques in Alzheimer's disease.  相似文献   

2.
Summary The cationic dyes ruthenium red (RR) and cuprolinic blue (CB) were used to preserve proteoglycans (PGs) for visualization at the ultrastructural level in brain tissue from seven cases of Alzheimer's disease (obtained at autopsy within 3–4 h after death). PGs were visualized as RR-positive granules specifically localized to the amyloid fibrils in neuritic plaques. In neurofibrillary tangles, RR granules were localized to the paired helical filaments and straight filaments usually at a consistent periodicity of 40–70 nm. CB, known to preserve PGs as short punctate filaments, also demonstrated PGs specifically localized to the amyloid fibrils in neuritic plaques and in association with paired helical filaments and straight filaments in neurofibrillary tangles. Persistent staining with CB at magnesium chloride concentrations of 0.3 and 0.7 M in the neuritic plaques suggested the presence of highly sulfated PGs, whereas abolishment of CB staining at 0.7 M magnesium chloride in the neurofibrillary tangles implied that different PGs and/or glycosaminoglycans were present in the neurofibrillary tangles. The specific ultrastructural localization of PGs to the characteristic lesions in Alzheimer's disease suggests that PGs are part of a complex structural network with amyloid fibrils in neuritic plaques and the filamentous structures present in neurofibrillary tangles.Supported by the Alzheimer's Disease Research Program of the American Health Assistance Foundation, The Alzheimer's Disease and Related Disorders Association Pilot Grant 87-019 and the Friends of Alzheimer's Research in conjunction with the University of Washington Alzheimer's Disease Research Center  相似文献   

3.
Studies of the molecular composition of the abnormal neuritic processes of the plaques in Alzheimer's disease (AD) have shown that these structures are immunoreactive with antibodies against growth-related molecules, synaptic/axonal proteins, and cytoskeletal proteins. These studies suggest that a subpopulation of abnormal neurites in the plaque are sprouting axons that eventually degenerate. To test this hypothesis further we studied the regional distribution of plaques in the hippocampus using a panel of monoclonal antibodies against synaptic proteins. With these antibodies we found a greater proportion of immunoreactive plaques compared to previous studies where a monoclonal antibody against synaptophysin was used. The most sensitive antobodies to detect neuritic plaques were SP11 and anti-p65, and the largest number of positive plaques was found in the entorhinal cortex and CA1 region. These results further support the theory that synaptic and axonal damage are involved in plaque formation in AD.Supported by NIH grants AG08201, AG08205, AG05131, AG10689 (to EM, RDT and LAH) and by a grant from the Alzheimer's Association/George F. Berlinger Memorial Faculty Scholar Award (to EM). WGH was supported by the British Columbia Health Research Foundation  相似文献   

4.
Activated microglia, overexpressing the potent neuroactive cytokine interleukin-1, have been implicated as a driving force in the evolution of diffuse amyloid deposits into diagnostic neuritic plaques in Alzheimer’s disease. To evaluate this role further, we used double-label immunohistochemistry to classify and quantify plaque-associated and non-plaque-associated activated interleukin-1-immunoreactive microglia in parahippocampal tissue from 11 patients with Alzheimer’s disease. These activated microglia were subclassified as primed (only slightly enlarged), enlarged, or phagocytic (enlarged with heterogeneous cytoplasmic contents). We further determined the distribution of these microglial subtypes among four defined plaque types. Most (84%) primed microglia were not plaque associated, although 13% were present in diffuse non-neuritic plaques and 3% were present in diffuse neuritic plaques. In contrast, most enlarged (55%) and phagocytic (91%) microglia were plaque associated. Of plaque-associated enlarged microglia, most (71%) were found in diffuse neuritic plaques with the remainder evenly distributed between diffuse non-neuritic and dense-core neuritic plaques (15% each). Of plaque-associated phagocytic microglia, a few were present in diffuse non-neuritic plaques (5%), but most were found in diffuse neuritic plaques (62%) and dense-core neuritic plaques (33%). These findings show preferential association of primed microglia with diffuse amyloid deposits and imply that microglial transformation from primed, to enlarged, to phagocytic types occurs in concert with the evolution of amyloid plaques from diffuse amyloid deposits to the neuritic β-amyloid plaque forms in Alzheimer’s disease. Microglial phagocytic activity in neuritic plaques may reflect involvement in the processing of diffuse amyloid into condensed β-amyloid, or in clearance of neuritic debris. Received: 15 January 1997 / Accepted: 17 March 1997  相似文献   

5.
Summary Brain sections from cases of human Creutzfeldt-Jakob disease, Gerstmann-Sträussler syndrome, kuru, and hamster scrapie containing amyloid were examined for the presence of sulfated glycosaminoglycans (GAGs), the anionic component of proteoglycans, using the sulfated Alcian blue method and Alcian blue technique with 0.3 M and 0.7 M magnesium chloride. These studies suggest that sulfated glycosaminoglycans are part of the CNS amyloid plaques in each of the above human prion disorders as well as in experimental scrapie. All the amyloid plaques stained positively with Alcian blue at 0.3 M, and less so at 0.7 M magnesium chloride indicating the presence of sulfated GAGs. Therefore, the amyloid plaques of prion diseases possess similar histochemical features to those found in Alzheimer's disease.Supported by Grant MT-3153 from the Medical Research Council of Canada, as well as research grants from the John Douglas French Foundation for Alzheimer's disease and the National Institutes of Health (NS22786, AG02132 and NS14069) and gifts from the R.J. Reynolds Industries, Sherman Fairchild Foundation, and Joseph and Stephaine Koret Foundation  相似文献   

6.
We sought to determine the pattern of ApoE immunoreactivity in mesial temporal lobe tissue from 12 Alzheimer patients, age 66–88, and to determine the distribution of this immunoreactivity among different plaque types representing hypothesized stages of plaque evolution. In these patients, the cortical area of ApoE immunoreactivity was 30% that of β-amyloid. Only 6% of diffuse non-neuritic amyloid deposits were even weakly ApoE immunoreactive (ApoE+). This is in contrast to our previous demonstration that microglia overexpressing interleukin-1 (IL-1) are present in most diffuse non-neuritic deposits. Eighty-three per cent of diffuse neuritic plaques and 86% of dense-core neuritic plaques were highly ApoE+, consistent with IL-1–induced astrocyte activation and synthesis of ApoE, resulting in the appearance of ApoE immunoreactivity in neuritic plaques. Dense-core non-neuritic ('burned out') plaques were only rarely (6%) ApoE+. These results, together with the known trophic and toxic effects of ApoE on neurites, suggest that plaque-associated ApoE contributes to the formation of overgrown degenerating (dystrophic) neurites in plaques. However, the fact that some neuritic plaques are not ApoE+ suggests contributions by additional trophic and toxic factors. Our results are also consistent with a role for ApoE in the condensation of diffuse amyloid deposits into a β-pleated-sheet form that occurs concomitant with dystrophic neurite formation in the neuritic β-amyloid plaques of Alzheimer's disease.  相似文献   

7.
Summary To clarify the association of microglia with senile plaques, the brains from 13 patients with Alzheimer's disease (AD) and 23 nondemented aged controls were investigated immunohistochemically by a double-labeling method using anti--protein antiserum and anti-ferritin antibody, which is a recently reported microglia marker. In addition, a quantitative analysis was performed. The senile plaques which appeared initially in the nondemented aged controls consisted of a diffuse type without any amyloid cores and these were found in the group aged 50–59 years. The great majority of them were found to contain no ferritin-positive microglia. The number and proportion (percentage) of microglia-containing diffuse plaques increased with age. Classical and compact plaques began to appear in the brains of the group aged 70 years and over, and practically all of them contained microglia. These results suggest that microglia are not associated with initial plaque formation, but correlate with amyloid core formation. In AD, the most prominent feature was that the diffuse plaques, which contained either no or only a few ferritin-positive microglia, increased markedly.Supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan  相似文献   

8.
Summary Both protein kinases and phosphoprotein phosphatases are important components of signal transduction systems in cells. Recent studies in Alzheimer's disease (AD) have shown abnormal protein phosphorylation in the cortex suggesting an alteration in these enzymes. In the present study, an antibody against CD45 was used to analyze the status of this protein phosphotyrosine phosphatase in AD. We studied and quantified the immunohistochemical and immunochemical distribution of this integral membrane protein in control and AD brain. We found that anti-CD45 immunostained the great majority of microglia, both resting and activated. These cells were Ricinus communis agglutinin I positive and glial fibrillary acidic protein and neurofilament negative. The AD frontal cortex showed a 35% (P<0.01) increase in the number of anti-CD45 immunoreactive microglia as compared with controls. These results were consistent with the immunoblot quantification of CD45 immunoreactivity following native gel electrophoresis. In AD, 30% of the CD45-immunostained microglia were clustered in the neuritic plaques (about six per plaque) while the remaining 70% were scattered in the neuropil. The AD hippocampus showed an increase in CD45-immunoreactive microglia in the molecular layer of the dentte gyrus. At the ultrastructural level, CD45 immunoreactivity was localized exclusively to the plasma membrane of the microglia. The presence of the anti-CD45 immunoreactivity in microglia suggests the possibility that they may require the presence of CD45 as a cell surface receptor which may regulate cell function through modulation of intracellular signaling.Supported by National Institutes of Health grants AG08205, AG08201, and AG05131, PEW Caritable Trust, and the Alzheimer's Association/George F. Berlinger Memorial Faculty Scholar Award  相似文献   

9.
Resolution process of cerebroparenchymal amyloid beta-protein (Abeta) deposition has become of increasing interest in the light of recent advance in the Abeta-vaccination therapy for Alzheimer's disease (AD). However, the neuropathological features of degraded and disappearing senile plaque remain poorly characterized, especially in the natural course of the disease. To clarify the natural removal processes of Abeta burden in the brain with AD, we devised a triple-step staining method: Bodian for dystrophic neurites, anti-glial fibrillary acidic protein for astrocytes, and anti-Abeta. We thus examined 24 autopsied AD brains. A novel form of senile plaques, termed 'remnant plaques', was identified. Remnant plaques were characterized by mesh-like astroglial fibrils within the entire plaque part, Abeta deposit debris exhibiting weak Abeta immunoreactivity, and only a few slender dystrophic neurites. In remnant plaques, amyloid burden was apparently decreased. The density of remnant plaques increased significantly with disease duration. Dual-labelling immunohistochemistry revealed many Abeta-immunoreactive granules in astrocytes and a modest number in microglia, both of which accumulated in senile plaques. We consider amyloid deposits of diffuse and neuritic plaques to be shredded by astrocytic processes from the marginal zone of plaques, and to gradually disintegrate into smaller compartments. Cerebroparenchymal Abeta deposits undergo degradation. After a long-standing resolution process, diffuse and neuritic plaques may finally proceed to remnant plaques. Astrocytes are actively engaged in the natural Abeta clearance mechanism in advanced stage AD brains, which may provide clues for developing new therapeutic strategies for AD.  相似文献   

10.
Neuritic (senile) plaques are a hallmark of the pathology found in the brain of patients afflicted with Alzheimer's disease (AD). Neuritic plaques have been considered to be composed of an amyloid core surrounded by dilated neurites, although the use of anti-beta/A4-protein antibody revealed the presence of diffuse plaques without a nuclear-like central mass or surrounding paired helical filament (PHF)-containing neuritic components. The presence of diffuse plaques without PHF-containing neuritic components strongly suggests that the formation of amyloid precedes the degeneration of neurites that surround amyloid. Diffuse plaques are thus considered to be an early marker of AD pathology. In this article, we report that diffuse plaques, possible markers of early AD pathology, are immunostained with anti-protein kinase C(beta II) [anti-PKC(beta II)] antibodies. The PKC(beta II)-immunoreacting components of the diffuse plaques extend from neurons embedded in the plaques. Immunoelectron microscopy of diffuse and mature neuritic plaques shows that PKC(beta II)-like immunoreactivity in the plaques is closely associated with membranous structures of fine neuronal processes apposed to the amyloid fibers. These fine neuronal processes are distinct from classical neurites found typically in mature neuritic plaques. Furthermore, biochemical analysis demonstrates that PKC abnormalities, but not other AD markers (ubiquitin and A68), were found in the neocortex of clinically nondemented individuals with cortical plaques. Therefore, the PKC alteration in neurons might be involved in the early pathophysiology of AD.  相似文献   

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