Alzheimer's β-Amyloid Peptide 1–42 Induces a Phagocytic Response in Murine Microglia

Abstract: β-Amyloid (Aβ) peptides are a key component of the senile plaques that characterize Alzheimer's disease. Cytokine-producing microglia have been shown to be intimately associated with amyloid deposits and have also been implicated as scavengers responsible for clearing Aβ deposits. However, little is known about the initial activation of these microglia or the effect of Aβ on phagocytosis. Murine BV-2 microglia were used to assess the effect of synthetic Aβ 1–42 on phagocytosis by quantifying uptake of fluorescent microspheres, acetylated low-density lipoproteins, and zymosan particles by flow cytometry. Aβ 1–42 stimulated microglial phagocytosis in a time- and dose-dependent manner. Aβ fibrils produced the greatest potentiation, and once activated, phagocytosis remained elevated after removal of Aβ from the cultures. Aβ-stimulated phagocytosis could be blocked if proteoglycans were first complexed to Aβ fibrils. These data suggest that Aβ fibrils act as an immune signal to stimulate microglial phagocytosis and that extracellular matrix molecules may modify Aβ function.     

Amyloid fibril formation by a synthetic peptide from a region of human acetylcholinesterase that is homologous to the Alzheimer's amyloid-beta peptide

A region near the C-terminus of human acetylcholinesterase (AChE) is weakly homologous with the N-terminus of the Alzheimer's disease amyloid-beta peptide. We report that a 14-amino acid synthetic polypeptide whose sequence corresponds to residues 586-599 of the human synaptic or T form of AChE assembles into amyloid fibrils under physiological conditions. The fibrils have all the classical characteristics of amyloid: they have a diameter of 6-7 nm and bind both Congo red and thioflavin-T. Furthermore, the kinetics of assembly indicate that fibril formation proceeds via a two-step nucleation-dependent polymerization pathway, and a transition in the peptide conformation from random coil to beta-sheet is observed during fibril formation using far-UV circular dichroism spectroscopy. We also show that the peptide in aggregated fibrillar form has a toxic effect upon PC-12 cells in vitro. AChE normally resides mainly on cholinergic neuronal membranes, but is abnormally localized to senile plaques in Alzheimer's disease. Recently, an in vitro interaction between AChE and A beta, the principal constituent of the amyloid fibrils in senile plaques, has been documented. The presence of a fibrillogenic region within AChE may be relevant to the interaction of AChE with amyloid fibrils formed by Abeta.     

Processing of Amyloid Precursor Protein in Human Primary Neuron and Astrocyte Cultures

Abstract: Increased production of amyloid β peptide (Aβ) is highly suspected to play a major role in Alzheimer's disease (AD) pathogenesis. Because Aβ deposits in AD senile plaques appear uniquely in the brain and are fairly restricted to humans, we assessed amyloid precursor protein (APP) metabolism in primary cultures of the cell types associated with AD senile plaques: neurons, astrocytes, and microglia. We find that neurons secrete 40% of newly synthesized APP, whereas glia secrete only 10%. Neuronal and astrocytic APP processing generates five C-terminal fragments similar to those observed in human adult brain, of which the most amyloidogenic higher-molecular-weight fragments are more abundant. The level of amyloidogenic 4-kDa Aβ exceeds that of nonamyloidogenic 3-kDa Aβ in both neurons and astrocytes. In contrast, microglia make more of the smallest C-terminal fragment and no detectable Aβ. We conclude that human neurons and astrocytes generate higher levels of amyloidogenic fragments than microglia and favor amyloidogenic processing compared with previously studied culture systems. Therefore, we propose that the higher amyloidogenic processing of APP in neurons and astrocytes, combined with the extended lifespan of individuals, likely promotes AD pathology in aging humans.     

Selective Aggregation of Endogenous β-Amyloid Peptide and Soluble Amyloid Precursor Protein in Cerebrospinal Fluid by Zinc

Abstract: Zinc added to buffered solutions of synthetic β-amyloid peptide (Aβ) has been reported to induce accelerated formation of insoluble aggregates. This observation suggests that zinc may play a role in the formation of senile plaques, which contain Aβ, in Alzheimer's disease. To test this hypothesis under conditions more representative of the brain, we investigated the ability of zinc to induce aggregation of Aβ in freshly drawn canine CSF, which contains the same sequence as human Aβ. Aggregates were separated from CSF by ultracentrifugation before and after incubation with zinc and assayed by quantitative western blotting and ELISA. We found that zinc induced the rapid aggregation of endogenous Aβ in CSF, with an EC₅₀ of 120–140 µ M . The reaction was specific, because most (≥95%) CSF protein remained soluble under conditions where most Aβ was insoluble, as assayed by scanning densitometry of Coomassie-stained gels. Staining of the precipitated material resulted in the visualization of punctate regions that were thioflavin positive or birefringent when stained with Congo red, suggesting the formation of amyloid-related structures. These results suggest that zinc could play a role in amyloid deposition, because there is overlap between the regions of the brain where zinc concentrations are highest and regions with the highest amyloid content. It is surprising that zinc induced the aggregation of endogenous soluble APP at lower concentrations than required for Aβ (EC₅₀ 80 µ M ). The possibility that zinc-induced aggregation of APP may precede the deposition of Aβ into plaques is discussed. Investigation of aggregation of Aβ in CSF will aid in assessing the biological relevance of other agents that have been reported to accelerate amyloid formation.     

Aggregation State-Dependent Activation of the Classical Complement Pathway by the Amyloid β Peptide

Abstract: Activation of the classical complement pathway has been widely investigated in recent years as a potential mechanism for the neuronal loss and neuritic dystrophy characteristic of Alzheimer's disease (AD) pathogenesis. We have previously shown that amyloid β peptide (Aβ) is a potent activator of complement, and recent evidence suggesting that the assembly state of Aβ is crucial to the progress of the disease prompted efforts to determine whether the ability of Aβ to activate the classical complement pathway is a function of the aggregation state of the peptide. In this report, we show that the fibrillar aggregation state of Aβ, as determined by thioflavin T fluorometry, electron microscopy, and staining with Congo red and thioflavine S, is precisely correlated with the ability of the peptide to induce the formation of activated fragments of the complement proteins C4 and C3. These results suggest that the classical complement pathway provides a mechanism whereby complement-dependent processes may contribute to neuronal injury in the proximity of fibrillar but not diffuse Aβ deposits in the AD brain.     

Proteoglycans and the acute-phase response in Alzheimer's disease brain

Alzheimer's disease is a dementing disorder affecting increasingly large numbers of individuals in the aging population. The characteristic neuropathologic changes of Alzheimer's disease are the deposition of extracellular is the major constituent of senile plaques. In addition to the A4 peptide, senile plaques contain a variety of molecular species, including proteoglycans and inflammatory components. The presence of proteoglycans in the amyloid deposits of Alzheimer's disease and of systemic amyloidoses suggests that these molecules play an active role in the pathogenesis of amyloidosis. However, the molecular mechanisms that lead to the codeposition of amyloid peptide with proteoglycans is still unknown. Recent evidence suggests that the metabolism of proteoglycans is altered in Alzheimer's disease patients. The acute-phase response observed in the brain of patients affected by Alzheimer's disease may be responsible for this effect. In this article, we discuss the role of proteoglycans in Alzheimer's disease, and the possible interactions between factors involved in brain inflammatory mechanisms and proteoglycans in the pathogenesis of Alzheimer's disease     

Effects of Sulfate Ions on Alzheimer β/A4 Peptide Assemblies: Implications for Amyloid Fibril-Proteoglycan Interactions

To model the possible involvement of sulfated proteoglycans in amyloidogenesis, we examined the influence of sulfate ions, heparan, and Congo red on the conformation and morphology of peptides derived from the Alzheimer beta/A4 amyloid protein. The peptides included residues 11-28, 13-28, 15-28, and 11-25 of beta/A4. Negative-stain electron microscopy revealed a sulfate-specific tendency of the preformed peptide fibrillar assemblies of beta(11-28), beta(13-28), and beta(11-25), but not beta(15-28), to undergo extensive lateral aggregation and axial growth into "macrofibers" that were approximately 0.1-0.2 micron wide by approximately 20-30 microns long. Such effects were observed at low sulfate concentrations (e.g., 5-50 mM) and could not be reproduced under comparable conditions with Na2HPO4, Na2SeO4, or NaCl. Macrofibers in NaCl were only observed at 1,000 mM. At physiological ionic strength of NaCl, fibril aggregation was observed only with addition of sulfate ions at 5-50 mM. Selenate ions, by contrast with sulfate ions, induced only axial and not substantial lateral aggregation of fibrils. X-ray diffraction indicated that the original cross-beta peptide conformation remained unchanged; however, sulfate binding did produce an intense approximately 65 A meridional reflection not recorded with control peptides. This new reflection probably arises from the periodic deposition of the electron-dense sulfate along the (long) axis of the fibril. The sulfate binding could provide sites for the binding of additional fibrils that generate the observed lateral and axial aggregation. The binding of heparan to beta(11-28) also produced extensive aggregation, suggesting that in vivo sulfated compounds can promote macrofibers. The amyloid-specific, sulfonated dye Congo red, even in the presence of sulfate ions, produced limited aggregation and reduced axial growth of the fibrils. Therefore, electrostatic interactions are important in the binding of exogenous compounds to amyloid fibrils. Our findings suggest that the sulfate moieties of certain molecules, such as glycosaminoglycans, may affect the aggregation and deposition of amyloid fibrils that are observed as extensive deposits in senile plaques and cerebrovascular amyloid.     

Pathologic Amyloid β-Protein Cell Surface Fibril Assembly on Cultured Human Cerebrovascular Smooth Muscle Cells

Abstract: Cerebrovascular amyloid β-protein (Aβ) deposition is a key pathological feature of Alzheimer's disease and hereditary cerebral hemorrhage with amyloidosis-Dutch type (HCHWA-D). Aβ_1–40 containing the E22Q HCHWA-D mutation, but not wild-type Aβ_1–40, potently induces several pathologic responses in cultured human cerebrovascular smooth muscle cells, including cellular degeneration and a robust increase in the levels of cellular Aβ precursor. In the present study, we show by several quantitative criteria, including thioflavin T fluorescence binding, circular dichroism spectroscopy, and transmission electron microscopic analysis, that at a concentration of 25 µ M neither HCHWA-D Aβ_1–40 nor wild-type Aβ_1–40 appreciably assembles into β-pleated sheet-containing fibrils in solution over a 6-day incubation period. In contrast, at the same concentrations, HCHWA-D Aβ_1–40, but not wild-type Aβ_1–40, selectively binds and assembles into abundant fibrils on the surfaces of cultured human cerebrovascular smooth muscle cells. The simultaneous addition of an equimolar concentration of the dye Congo red prevents the cell surface fibril assembly of HCHWA-D Aβ_1–40. Moreover, Congo red effectively blocks the key pathologic responses induced by HCHWA-D Aβ_1–40 in these cells. The present findings suggest that the surface of human cerebrovascular smooth muscle cells may selectively orchestrate the assembly of pathogenic Aβ fibrils and that cell surface Aβ fibril formation plays an important role in causing the pathologic responses in these cells.     

Alzheimer Aβ Amyloid Forms an Inhibitory Neuronal Substrate

Abstract: Alzheimer's disease (AD) is identified by the accumulation of amyloid plaques, neurofibrillary degeneration, and the accompanying neuronal loss. AD amyloid assembles into compact fibrous deposits from the amyloid β(Aβ) protein, which is a proteo-lytic fragment of the membrane-associated amyloid precursor protein. To examine the effects of amyloid on neuron growth, a hybrid mouse motoneuron cell line (NSC34) exhibiting spontaneous process formation was exposed to artificial "plaques" created from aggregated synthetic Aβ peptides. These correspond to full-length Aβ residues 1–40 (Aβ1–40), an internal β-sheet region comprising residues 11–28 (Aβ11–28), and a proposed toxic fragment comprising residues 25–35 (Aβ25–35). Fibers were immobilized onto culture dishes, and addition of cells to these in vitro plaques revealed that Aβ was not a permissive substrate for cell adhesion. Neurites in close contact with these deposits displayed abnormal swelling and a tendency to avoid contact with the Aβ fibers. In contrast, Aβ did not affect the adhesion or growth of rat astrocytes, implicating a specific Aβ-neuron relationship. The inhibitory effects were also unique to Aβ as no response was observed to deposits of pancreatic islet amyloid poly-peptide fibers. Considering the importance of cell adhesion in neurite elongation and axonal guidance, the antiadhesive properties of Aβ amyloid plaques found in vivo may contribute to the neuronal loss responsible for the clinical manifestations of AD.     

Real-time and single fibril observation of the formation of amyloid beta spherulitic structures

In Alzheimer disease, amyloid beta, a 39-43-residue peptide produced by cleavage from a large amyloid precursor protein, undergoes conformational change to form amyloid fibrils and deposits as senile amyloid plaques in the extracellular cerebral cortices of the brain. However, the mechanism of how the intrinsically linear amyloid fibrils form spherical senile plaques is unknown. With total internal reflection fluorescence microscopy combined with the use of thioflavin T, an amyloid-specific fluorescence dye, we succeeded in observing the formation of the senile plaque-like spherulitic structures with diameters of around 15 microm on the chemically modified quartz surface. Real-time observation at a single fibrillar level revealed that, in the absence of tight contact with the surface, the cooperative and radial growth of amyloid fibrils from the core leads to a huge spherulitic structure. The results suggest the underlying physicochemical mechanism of senile plaque formation, essential for obtaining insight into prevention of Alzheimer disease.     

The relationship between senile plaques and cerebral blood vessels in Alzheimer's disease and senile dementia. Morphological mechanism of senile plaque production

Several kinds of senile plaque found in 6 brains (4 from patients with Alzheimer's disease and 2 from patients with senile dementia) were examined in serial sections by light electron microscopy. The results obtained were as follows. All the senile plaques contained at least some amyloid fibrils, and these seemed to be produced at the basement membranes of capillary endothelial cells and projected into the surrounding parenchyma. Even when the senile plaques themselves appeared to lack amyloid fibrils by light microscopy, at least one degenerable capillary containing amyloid fibrils was demonstrable when serial sections were examined ultrastructurally. The findings described above suggest that the amyloid fibrils which form the cores of the several kinds of senile plaque, seem to be produced at the basement membrane of the endothelial cell. It is speculated that the capillary degeneration with the formation of amyloid fibrils may be primary change in the genesis of senile plaques.     

Complement component C1q inhibits beta-amyloid- and serum amyloid P-induced neurotoxicity via caspase- and calpain-independent mechanisms

Alzheimer's disease is a neurodegenerative disorder characterized by neuronal loss, β-amyloid (Aβ) plaques, and neurofibrillary tangles. Complement protein C1q has been found associated with fibrillar Aβ deposits, however the exact contributions of C1q to Alzheimer's disease is still unknown. There is evidence that C1q, as an initiator of the inflammatory complement cascade, may accelerate disease progression. However, neuronal C1q synthesis is induced after injury/infection suggesting that it may be a beneficial response to injury. In this study, we report that C1q enhances the viability of neurons in culture and protects neurons against Aβ- and serum amyloid P (SAP)-induced neurotoxicity. Investigation of potential signaling pathways indicates that caspase and calpain are activated by Aβ, but C1q had no effect on either of these pathways. Interestingly, SAP did not induce caspase and calpain activation, suggesting that C1q neuroprotection is in distinct from caspase and calpain pathways. In contrast to Aβ- and SAP-induced neurotoxicity, neurotoxicity induced by etoposide or FCCP was unaffected by the addition of C1q, indicating pathway selectivity for C1q neuroprotection. These data support a neuroprotective role for C1q which should be further investigated to uncover mechanisms which may be therapeutically targeted to slow neurodegeneration via direct inhibition of neuronal loss.     

Amyloid Precursor Protein Metabolism in Primary Cell Cultures of Neurons, Astrocytes, and Microglia

Abstract: Amyloid precursor protein (APP) gives rise by proteolytic processing to the amyloid β peptide (Aβ) found abundantly in cerebral senile plaques of individuals with Alzheimer's disease. APP is highly expressed in the brain. To assess the source of cerebral Aβ, the metabolism of APP was investigated in the major cell types of the newborn rat cerebral cortex by pulse/chase labeling and immunoprecipitation of the APP and APP metabolic fragments. We describe a novel C-terminally truncated APP isoform that appears to be made only in neurons. The synthesis, degradation, and metabolism of APP were quantified by phosphorimaging in neurons, astrocytes, and microglia. The results show that although little APP is metabolized through the amyloidogenic pathways in each of the three cultures, neurons appear to generate more Aβ than astrocytes or microglia.     

Amyloid beta and amylin fibrils induce increases in proinflammatory cytokine and chemokine production by THP-1 cells and murine microglia

Activated microglia surrounding amyloid beta-containing senile plaques synthesize interleukin-1, an inflammatory cytokine that has been postulated to contribute to Alzheimer's disease pathology. Studies have demonstrated that amyloid beta treatment causes increased cytokine release in microglia and related cell cultures. The present work evaluates the specificity of this cellular response by comparing the effects of amyloid beta to that of amylin, another amyloidotic peptide. Both lipopolysaccharide-treated THP-1 monocytes and mouse microglia showed significant increases in mature interleukin-1beta release 48 h following amyloid beta or human amylin treatment, whereas nonfibrillar rat amylin had no effect on interleukin-1beta production by THP-1 cells. Lipopolysaccharide-stimulated THP-1 cells treated with amyloid beta or amylin also showed increased release of the proinflammatory cytokines tumor necrosis factor-alpha and interleukin-6, as well as the chemokines interleukin-8 and macrophage inflammatory protein-1alpha and -1beta. THP-1 cells incubated with fibrillar amyloid beta or amylin in the absence of lipopolysaccharide also showed significant increases of both interleukin-1beta and tumor necrosis factor-alpha mRNA. Furthermore, treatment of THP-1 cells with amyloid fibrils resulted in an elevated expression of the immediate-early genes c-fos and junB. These studies provide further evidence that fibrillar amyloid peptides can induce signal transduction pathways that initiate an inflammatory response that is likely to contribute to Alzheimer's disease pathology.     

Congo red and thioflavin-T analogs detect Abeta oligomers

Several small molecule ligands for amyloid-β (Aβ) fibrils deposited in brain have been developed to facilitate radiological diagnosis of Alzheimer's disease (AD). Recently, the build-up of Aβ oligomers (AβO) in brain has been recognized as an additional hallmark of AD and may play a more significant role in early stages. Evidence suggests that quantitative assessment of AβO would provide a more accurate index of therapeutic effect of drug trials. Therefore, there is an urgent need to develop methods for efficient identification as well as structural analysis of AβO. We found that some well established amyloid ligands, analogs of Congo red and thioflavin-T (ThT), bind AβO with high affinity and detect AβO in vitro and in vivo . Binding studies revealed the presence of binding sites for Congo red- and thioflavin-T-analogs on AβO. Furthermore, these ligands can be used for imaging intracellular AβO in living cells and animals and as positive contrast agent for ultrastructural imaging of AβO, two applications useful for structural analysis of AβO in cells. We propose that by improving the binding affinity of current ligands, in vivo imaging of AβO is feasible by a 'signal subtraction' procedure. This approach may facilitate the identification of individuals with early AD.     

Rapid Degeneration of Cultured Human Brain Pericytes by Amyloid β Protein

Abstract: Amyloid β protein (Aβ) deposition in the cerebral arterial and capillary walls is one of the major characteristics of brains from patients with Alzheimer's disease and hereditary cerebral hemorrhage with amyloidosis-Dutch type (HCHWA-D). Vascular Aβ deposition is accompanied by degeneration of smooth muscle cells and pericytes. In this study we found that Aβ_1–40 carrying the "Dutch" mutation (HCHWA-D Aβ_1–40) as well as wild-type Aβ_1–42 induced degeneration of cultured human brain pericytes and human leptomeningeal smooth muscle cells, whereas wild-type Aβ_1–40 and HCHWA-D Aβ_1–42 were inactive. Cultured brain pericytes appeared to be much more vulnerable to Aβ-induced degeneration than leptomeningeal smooth muscle cells, because in brain pericyte cultures cell viability already decreased after 2 days of exposure to HCHWA-D Aβ_1–40, whereas in leptomeningeal smooth muscle cell cultures cell death was prominent only after 4–5 days. Moreover, leptomeningeal smooth muscle cell cultures were better able to recover than brain pericyte cultures after short-term treatment with HCHWA-D Aβ_1–40. Degeneration of either cell type was preceded by an increased production of cellular amyloid precursor protein. Both cell death and amyloid precursor protein production could be inhibited by the amyloid-binding dye Congo red, suggesting that fibril assembly of Aβ is crucial for initiating its destructive effects. These data imply an important role for Aβ in inducing perivascular cell pathology as observed in the cerebral vasculature of patients with Alzheimer's disease or HCHWA-D.     

Amyloid Angiopathy of Alzheimer''s Disease: Amino Acid Composition and Partial Sequence of a 4,200-Dalton Peptide Isolated from Cortical Microvessels

The cardinal lesions of Alzheimer's disease are neurofibrillary tangles, senile neuritic plaques, and vascular amyloid, the latter generally involving cortical arteries and small arterioles. All three lesions are composed of amyloid-like, beta-pleated sheet fibrils. Recently, a 4,200-dalton peptide has been isolated from extraparenchymal meningeal vessels, neuritic plaques, and neurofibrillary tangles. The assumption of N-terminal homogeneity in vascular amyloid has been used as an argument for a neuronal (versus blood) origin of the peptide. However, intracortical microvessels from Alzheimer's disease have not been previously isolated. The present studies describe the isolation of a microvessel fraction from Alzheimer's disease and control fresh autopsy human brain. Alzheimer's disease isolated brain microvessels that were extensively laden with amyloid and control microvessels were solubilized in 90% formic acid and analyzed by urea sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The arteriole fraction from the Alzheimer's subject with extensive amyloid angiopathy contained a unique 4,200-dalton peptide, whereas the arterioles or capillaries isolated from two controls and two Alzheimer's disease subjects without angiopathy did not. This peptide was purified by HPLC and amino acid composition analysis showed the peptide is nearly identical to the 4,200-dalton peptide recently isolated from neuritic plaques or from neurofibrillary tangles. Sequence analysis revealed N-terminal heterogeneity. The N-terminal sequence was: Asp-Ala-Glu-Phe-Arg-His-Asp-Ser-Gly-Tyr, which is identical to the N-terminal sequence of the 4,200-dalton peptide isolated previously from extraparenchymal meningeal vessels and neuritic plaques.(ABSTRACT TRUNCATED AT 250 WORDS)     

α2-Macroglobulin Attenuates β-Amyloid Peptide 1–40 Fibril Formation and Associated Neurotoxicity of Cultured Fetal Rat Cortical Neurons

Abstract: β-Amyloid peptides (Aβ) are deposited in an aggregated fibrillar form in both diffuse and senile plaques in the brains of patients with Alzheimer's disease. The neurotoxicity of Aβ in cultured neurons is dependent on its aggregation state, but the factors contributing to aggregation and fibril formation are poorly understood. In the present study, we investigated whether α₂-macroglobulin (α₂M), a protein present in neuritic plaques and elevated in Alzheimer's disease brain, is a potential regulatory factor for Aβ fibril formation. Previous studies in our laboratory have shown that α₂M is an Aβ binding protein. We now report that, in contrast to another plaque-associated protein, α₁-antichymotrypsin, α₂M coincubated with Aβ significantly reduces aggregation and fibril formation in vitro. Additionally, cultured fetal rat cortical neurons are less vulnerable to the toxic actions of aged Aβ following pretreatment with α₂M. We postulate that α₂M is able to maintain Aβ in a soluble state, preventing fibril formation and associated neurotoxicity.     

Brain Expression of Apolipoproteins E, J, and A-I in Alzheimer's Disease

Abstract: Inheritance of the ε4 allele of apolipoprotein (apo) E is associated with increased risk of Alzheimer's disease (AD) and with increased β-amyloid peptide (Aβ) deposition in the cortex. Apo E is a member of a family of exchangeable apos, characterized by the presence of amphipathic α-helical segments that allow these molecules to act as surfactants on the surface of lipoprotein particles. Two members of this family, apo E and apo J, have been shown to bind soluble Aβ, and both are associated with senile plaques in the AD cortex. We now have studied the pattern of brain apo expression and found that five members of this class are present: apo A-I, A-IV, D, E, and J. By contrast, apos A-II, B, and C-II were not detectable. Immunohistochemistry revealed that, in addition to apo E and apo J, apo A-I immunostained occasional senile plaques in AD cortex. Immunoblot analysis showed no difference in the relative amounts of any of these apos in tissue homogenates of frontal lobe from AD or control patients. Comparison by APO E genotype showed no differences in the amount of apo E in brain among APO E ε3/3, ε3/4, or ε4/4 individuals; however, a significant decrease in the amount of apo J was associated with the APO E ε4 allele. No differences in apo J levels were detected in CSF samples of AD subjects. We propose that several members of the exchangeable apo family may interact with Aβ deposits in senile plaques through common amphipathic α-helical domains. Competition among these molecules for binding of Aβ or Aβ aggregates may influence the deposition of Aβ in senile plaques.     

Peripheral distribution of dermatan sulfate proteoglycans (decorin) in amyloid-containing plaques and their presence in neurofibrillary tangles of Alzheimer's disease.

We used a polyclonal antibody and a mixture of three monoclonal antibodies (MAb), all recognizing the protein core of the small dermatan sulfate proteoglycan (DSPG) (known as PG-II or decorin) derived from human skin fibroblasts, to immunolocalize this molecule in the characteristic lesions in Alzheimer's brain. All antibodies demonstrated positive decorin immunostaining in both the amyloid deposits of neuritic plaques (NPs) and the filamentous structures within neurofibrillary tangles (NFTs). Unlike heparan sulfate proteoglycans (HSPGs), which tend to be evenly distributed throughout NPs containing amyloid fibrils, decorin was primarily localized to the periphery of the spherically shaped amyloid plaques and to the edges of amyloid fibril bundles within the plaque periphery. Decorin was also immunolocalized to the paired helical and straight filaments within NFTs and to collagen fibrils surrounding blood vessels. The unusual distribution of decorin confined to the periphery of amyloid plaques in AD brain suggests that this particular PG may play an important role in the development of the amyloid plaque.