Senile Plaques In Alzheimer's Disease Brain Research Articles

Zinc and Copper Differentially Modulate Amyloid Precursor Protein Processing by γ-Secretase and Amyloid-β Peptide Production

Recent evidence suggests involvement of biometal homeostasis in the pathological mechanisms in Alzheimer's disease (AD). For example, increased intracellular copper or zinc has been linked to a reduction in secreted levels of the AD-causing amyloid-β peptide (Aβ). However, little is known about whether these biometals modulate the generation of Aβ. In the present study we demonstrate in both cell-free and cell-based assays that zinc and copper regulate Aβ production by distinct molecular mechanisms affecting the processing by γ-secretase of its Aβ precursor protein substrate APP-C99. We found that Zn2+ induces APP-C99 dimerization, which prevents its cleavage by γ-secretase and Aβ production, with an IC50 value of 15 μm Importantly, at this concentration, Zn2+ also drastically raised the production of the aggregation-prone Aβ43 found in the senile plaques of AD brains and elevated the Aβ43:Aβ40 ratio, a promising biomarker for neurotoxicity and AD. We further demonstrate that the APP-C99 histidine residues His-6, His-13, and His-14 control the Zn2+-dependent APP-C99 dimerization and inhibition of Aβ production, whereas the increased Aβ43:Aβ40 ratio is substrate dimerization-independent and involves the known Zn2+ binding lysine Lys-28 residue that orientates the APP-C99 transmembrane domain within the lipid bilayer. Unlike zinc, copper inhibited Aβ production by directly targeting the subunits presenilin and nicastrin in the γ-secretase complex. Altogether, our data demonstrate that zinc and copper differentially modulate Aβ production. They further suggest that dimerization of APP-C99 or the specific targeting of individual residues regulating the production of the long, toxic Aβ species, may offer two therapeutic strategies for preventing AD.

Determination of critical nucleation number for a single nucleation amyloid-β aggregation model

Aggregates of amyloid-β (Aβ) peptide are known to be the key pathological agents in Alzheimer disease (AD). Aβ aggregates to form large, insoluble fibrils that deposit as senile plaques in AD brains. The process of aggregation is nucleation–dependent in which the formation of a nucleus is the rate–limiting step, and controls the physiochemical fate of the aggregates formed. Therefore, understanding the properties of nucleus and pre-nucleation events will be significant in reducing the existing knowledge–gap in AD pathogenesis. In this report, we have determined the plausible range of critical nucleation number (n*), the number of monomers associated within the nucleus for a homogenous aggregation model with single unique nucleation event, by two independent methods: A reduced-order stability analysis and ordinary differential equation based numerical analysis, supported by experimental biophysics. The results establish that the most likely range of n* is between 7 and 14 and within, this range, n* = 12 closely supports the experimental data. These numbers are in agreement with those previously reported, and importantly, the report establishes a new modeling framework using two independent approaches towards a convergent solution in modeling complex aggregation reactions. Our model also suggests that the formation of large protofibrils is dependent on the nature of n*, further supporting the idea that pre-nucleation events are significant in controlling the fate of larger aggregates formed. This report has re-opened an old problem with a new perspective and holds promise towards revealing the molecular events in amyloid pathologies in the future.

Unfolded Protein Response and PERK Kinase as a New Therapeutic Target in the Pathogenesis of Alzheimer's Disease.

Recent evidence suggests that the development of Alzheimer's disease (AD) and related cognitive loss is due to mutations in the Amyloid Precursor Protein (APP) gene on chromosome 21 and increased activation of eukaryotic translation initiation factor-2α (eIF2α) phosphorylation. The high level of misfolded and unfolded proteins loading in Endoplasmic Reticulum (ER) lumen triggers ER stress and as a result Unfolded Protein Response (UPR) pathways are activated. Stress-dependent activation of the protein kinase RNA-like endoplasmic reticulum kinase (PERK) leads to the significant elevation of phospho-eIF2α. That attenuates general translation and, on the other hand, promotes the preferential synthesis of Activating Transcription Factor 4 (ATF4) and secretase β (BACE1) - a pivotal enzyme responsible for the initiation of the amyloidogenic pathway resulting in the generation of the amyloid β (Aβ) variant with high ability to form toxic senile plaques in AD brains. Moreover, excessive, long-term stress conditions may contribute to inducing neuronal death by apoptosis as a result of the overactivated expression of pro-apoptotic proteins via ATF4. These findings allow to infer that dysregulated translation, increased expression of BACE1 and ATF4, as a result of eIF2α phosphorylation, may be a major contributor to structural and functional neuronal loss resulting in memory impairment. Thus, blocking PERK-dependent eIF2α phosphorylation through specific, small-molecule PERK branch inhibitors seems to be a potential treatment strategy for AD individuals. That may contribute to the restoration of global translation rates and reduction of expression of ATF4 and BACE1. Hence, the treatment strategy can block accelerated β -amyloidogenesis by reduction in APP cleaving via the BACE1-dependent amyloidogenic pathway.

Clusterin Associates Specifically with Aβ40 in Alzheimer's Disease Brain Tissue

AbstractGenome‐wide association studies have pointed to clusterin (apolipoprotein J) as being linked to the occurrence of Alzheimer's disease (AD); studies have identified the protein as a possible biomarker. The association between clusterin and senile plaques in AD brain is well known, and clusterin levels in AD brain are 40% higher than that in control subjects. The present study investigates, immunohistochemically, the association between clusterin and Aβ peptides in AD and control cortex. A unique and specific association between clusterin and Aβ40 was observed in plaques in the cerebral cortex from AD subjects in that only plaques that contained Aβ40 showed clusterin immunoreactivity, while the many plaques with Aβ42 alone lacked clusterin labeling. Cerebrovascular Aβ in AD brain generally lacked Aβ42 but was positively labeled by both the Aβ40 and the clusterin antibodies. In control subjects, however, Aβ40 was absent from plaques, although very occasional plaques were found to be labeled by both the Aβ42 and the clusterin antibodies. Overall, in AD, but not aged control brain, clusterin was associated specifically with the Aβ40 form of Aβ in the brain. The lack of clusterin in association with Aβ42 may be a significant feature in neuronal loss and neurodegeneration in the disease state.

Changes of nuclear factor and inflammatory chemotactic factors in brain of patients with Alzheimer's disease

To investigate the changes of nuclear factor (NF-)κBp65 and inflammatory chemotactic factors including monocyte chemoattractant protein 1 (MCP-1/CCL-2), macrophage inflammatory protein 1α (MIP-1α/CCL-3), glial fibrillary acidic protein (GFAP) in brains of the patients with Alzheimer's disease (AD) and reveal the correlation of these factors. Ten patients with AD and 8 age-matched control subjects were selected in the study. Immunohistochemistry was performed to determine the protein expression of NF-κBp65, MCP-1, MIP-1α and GFAP. Double-immunohistochemistry was used to detect the expression of GFAP and β-amyloid peptide 1-42 (Aβ(1-42)) in the hippocampus, temporal and frontal cortices. As compared to age-matched controls (the numbers of the positively stained neuronal cells: 0.31 ± 0.20, 0.25 ± 0.20 and 0.25 ± 0.20, respectively), the immunoreactivities of NF-κBp65 in the hippocampus and the temporal and frontal cortices (numbers of the positively stained cells: 3.6 ± 1.5, 2.2 ± 1.2 and 2.2 ± 1.2, respectively) were significantly increased in AD brains. The levels of MCP-1 and MIP-1α in the hippocampus, and the temporal and frontal cortices (numbers of the positively stained neuronal cells: 8.0 ± 1.3, 8.8 ± 1.0, 9.3 ± 1.4, respectively;and 8.1 ± 1.5, 12.5 ± 1.1, 6.4 ± 1.1, respectively) with AD were significantly higher than those of controls (the numbers of the positive neuronal cells: 4.5 ± 0.9, 4.5 ± 0.6, 4.0 ± 1.8, respectively; and 5.0 ± 1.9, 6.3 ± 2.2, 3.8 ± 1.5, respectively). An increased number of glial cells stained with GFAP were observed to extensively distribute around the senile plaques in AD brains. There were significant correlations between NF-κBp65 and these inflammatory chemotactic factors in AD brains. Correlative expressions of NF and inflammatory chemotactic factors were found in the brains of AD patients, through a mechanism that may involve the inflammatory response induced by Aβ in the processing of AD.

Neuroinflammation, AD, and Dementia

Neuroinflammation, AD, and Dementia

Formation of soluble amyloid oligomers and amyloid fibrils by the multifunctional protein vitronectin

BackgroundThe multifunctional protein vitronectin is present within the deposits associated with Alzheimer disease (AD), age-related macular degeneration (AMD), atherosclerosis, systemic amyloidoses, and glomerulonephritis. The extent to which vitronectin contributes to amyloid formation within these plaques, which contain misfolded, amyloidogenic proteins, and the role of vitronectin in the pathophysiology of the aforementioned diseases is currently unknown. The investigation of vitronectin aggregation is significant since the formation of oligomeric and fibrillar structures are common features of amyloid proteins.ResultsWe observed vitronectin immunoreactivity in senile plaques of AD brain, which exhibited overlap with the amyloid fibril-specific OC antibody, suggesting that vitronectin is deposited at sites of amyloid formation. Of particular interest is the growing body of evidence indicating that soluble nonfibrillar oligomers may be responsible for the development and progression of amyloid diseases. In this study we demonstrate that both plasma-purified and recombinant human vitronectin readily form spherical oligomers and typical amyloid fibrils. Vitronectin oligomers are toxic to cultured neuroblastoma and retinal pigment epithelium (RPE) cells, possibly via a membrane-dependent mechanism, as they cause leakage of synthetic vesicles. Oligomer toxicity was attenuated in RPE cells by the anti-oligomer A11 antibody. Vitronectin fibrils contain a C-terminal protease-resistant fragment, which may approximate the core region of residues essential to amyloid formation.ConclusionThese data reveal the propensity of vitronectin to behave as an amyloid protein and put forth the possibilities that accumulation of misfolded vitronectin may contribute to aggregate formation seen in age-related amyloid diseases.

Hematopoietic Prostaglandin D Synthase and DP1 Receptor Are Selectively Upregulated in Microglia and Astrocytes Within Senile Plaques From Human Patients and in a Mouse Model of Alzheimer Disease

Prostaglandin (PG) D2 is produced in activated microglia by the action of hematopoietic PGD synthase (HPGDS) and plays important roles in neuroinflammation. Because the fact that neuroinflammation accelerates progression of Alzheimer disease (AD) has been documented, we investigated whether PGD2 is also involved in the pathology of AD. Here, we report that the level of the mRNA of the receptor for PGD2 (DP1) was increased in AD brains compared with the level in non-AD brains. Immunocytochemical analysis showed HPGDS expression to be localized in the microglia surrounding senile plaques. In situ hybridization studies revealed that DP1 mRNA was specifically localized in microglia and reactive astrocytes within senile plaques of AD brains. In the brain of Tg2576 mice, a model of AD, HPGDS and DP1 proteins were mainly localized immunocytochemically in microglia and astrocytes in the plaques, and the levels of their mRNAs increased in parallel with amyloid beta deposition. These results indicate that PGD2 may act as a mediator of plaque-associated inflammation in AD brain and may explain the pharmacologic mechanisms underlying the favorable response of patients with AD to nonsteroidal anti-inflammatory drugs.

The inflammation-sensitive protein alpha 1-anti-chymotrypsin neutralizes fibrillar aggregation and cytotoxicity of the beta-amyloid peptide more effectively than alpha 1-antitrypsin

Objectives: A neuroinflammatory process, triggered by amyloid-beta (Aβ)-peptide, is thought to play a central role in the neurodegenerative process leading to Alzheimer's disease (AD). Aβ 25–35 retains the functionality of Aβ 42 and was employed to investigate the effects of inflammation-sensitive proteins (ISPs) α1-antichymotrypsin (A1ACT) and α1-antitrypsin (A1AT) on fibrillar aggregation and cytotoxicity. Design and methods: Inhibitory concentrations of the ISPs were determined in an established human red blood cell lysis model of Aβ-cytotoxicity. For studies of Aβ-fibrillar aggregation CSF levels of A1ACT (0.041 μM)/A1AT (0.11 μM) were incubated with Congo Red dye 25 μM + Aβ 25–35 10 μM noting the formation of visible aggregates and spectrophotometric changes over 24 h. Results: A1ACT at CSF reported levels inhibited fibrillar aggregation and cytotoxicity while A1AT at CSF reported levels failed to cause a similar inhibition. Conclusions: A1ACT neutralizes fibrillar aggregation and cytotoxicity of Aβ-peptide more effectively than A1AT. Both proteins are known to be co-deposited with Aβ within senile plaques of AD brains.

RNA Interference Silencing of the Adaptor Molecules ShcC and Fe65 Differentially Affect Amyloid Precursor Protein Processing and Aβ Generation

The amyloid precursor protein (APP) and its pathogenic by-product amyloid-beta protein (Abeta) play central roles in Alzheimer disease (AD) neuropathogenesis. APP can be cleaved by beta-secretase (BACE) and alpha-secretase to produce APP-C99 and APP-C83. These C-terminal fragments can then be cleaved by gamma-secretase to produce Abeta and p3, respectively. p3 has been reported to promote apoptosis, and Abeta is the key component of senile plaques in AD brain. APP adaptor proteins with phosphotyrosine-binding domains, including ShcA (SHC1), ShcC (SHC3), and Fe65 (APBB1), can bind to and interact with the conserved YENPTY motif in the APP-C terminus. Here we have described for the first time the effects of RNA interference (RNAi) silencing of ShcA, ShcC, and Fe65 expression on APP processing and Abeta production. RNAi silencing of ShcC led to reductions in the levels of APP-C-terminal fragments (APP-CTFs) and Abeta in H4 human neuroglioma cells stably overexpressing full-length APP (H4-FL-APP cells) but not in those expressing APP-C99 (H4-APP-C99 cells). RNAi silencing of ShcC also led to reductions in BACE levels in H4-FL-APP cells. In contrast, RNAi silencing of the homologue ShcA had no effect on APP processing or Abeta levels. RNAi silencing of Fe65 increased APP-CTF levels, although also decreasing Abeta levels in H4-FL-APP cells. These findings suggest that pharmacologically blocking interaction of APP with ShcC and Fe65 may provide novel therapeutic strategies against AD.

ADAM10 Activation Is Required for Green Tea (–)-Epigallocatechin-3-gallate-induced α-Secretase Cleavage of Amyloid Precursor Protein

Recently, we have shown that green tea polyphenol (-)-epigallocatechin-3-gallate (EGCG) exerts a beneficial role on reducing brain Abeta levels, resulting in mitigation of cerebral amyloidosis in a mouse model of Alzheimer disease. EGCG seems to accomplish this by modulating amyloid precursor protein (APP) processing, resulting in enhanced cleavage of the alpha-COOH-terminal fragment (alpha-CTF) of APP and corresponding elevation of the NH(2)-terminal APP product, soluble APP-alpha (sAPP-alpha). These beneficial effects were associated with increased alpha-secretase cleavage activity, but no significant alteration in beta-or gamma-secretase activities. To gain insight into the molecular mechanism whereby EGCG modulates APP processing, we evaluated the involvement of three candidate alpha-secretase enzymes, a-disintegrin and metalloprotease (ADAM) 9, 10, or 17, in EGCG-induced non-amyloidogenic APP metabolism. Results show that EGCG treatment of N2a cells stably transfected with "Swedish" mutant human APP (SweAPP N2a cells) leads to markedly elevated active ( approximately 60 kDa mature form) ADAM10 protein. Elevation of active ADAM10 correlates with increased alpha-CTF cleavage, and elevated sAPP-alpha. To specifically test the contribution of ADAM10 to non-amyloidogenic APP metabolism, small interfering RNA knockdown of ADAM9, -10, or -17 mRNA was employed. Results show that ADAM10 (but not ADAM9 or -17) is critical for EGCG-mediated alpha-secretase cleavage activity. In summary, ADAM10 activation is necessary for EGCG promotion of non-amyloidogenic (alpha-secretase cleavage) APP processing. Thus, ADAM10 represents an important pharmacotherapeutic target for the treatment of cerebral amyloidosis in Alzheimer disease.

Vicious Cycles Within the Neuropathophysiologic Mechanisms of Alzheimers Disease

Rigorous scientific research has identified multiple interactive mechanisms that parallel and are likely causative of the development of Alzheimer's disease (AD). Causative mechanisms include genomics, the creation of amyloid beta (Abeta), factors inhibiting the Abeta removal process, the transformation of Abeta to its toxic forms (various forms of Abeta aggregation), and lastly the oxidative, inflammatory, and other effects of toxic Abeta. Fibrillar beta-amyloid peptide, a major component of senile plaques in AD brain, is known to induce microglial-mediated neurotoxicity under certain conditions, but some recent studies support the notion that Abeta oligomers are the primary neurotoxins. Abeta-42 oligomers that are soluble and highly neurotoxic, referred to as Abeta-derived diffusible ligands (ADDLs), assemble under conditions that block fibril formation. These oligomers bind to dendrite surfaces in small clusters with ligand-like specificity and are capable of destroying hippocampal neurons at nanomolar concentrations. Evidence is presented that AD is triggered by these soluble, neurotoxic assemblies of Abeta rather than the late stage pathology landmarks of amyloid plaques and tangles. The premise is that AD symptoms stem from aberrant nerve cell signaling and synaptic failure rather than nerve cell death, which nevertheless follows and exacerbates the initial pathologies of AD. The defective clearance of amyloid leads to amyloid angiopathy that in turn perpetuates hypoperfusion that affects formation as well as absorption of CSF thereby altering clearance of amyloid and promoting vascular and parenchymal deposition[1]. Hypoperfusion, the defective clearance of amyloid, and resultant increase in amyloid deposition thus represent a vicious cycle. Chronic vascular hypoperfusion-induced mitochondrial failure results in oxidative damage, which drives caspase 3-mediated Abeta peptide secretion and enhances amyloidogenic APP processing. Intracellular Abeta accumulation in turn promotes a significant oxidative and inflammatory mechanism that generates a vicious cycle of Abeta generation and oxidation, each accelerating the other. Abeta activates astrocytes that add to the oxidative imbalance, upregulate the expression of APP via TGF-beta, and are capable of expressing BACE1. Each of these 3 actions accelerates the larger cycle of cholinergic neuron destruction. As oxidative stress induces lesions of cholinergic nuclei producing a reduction in cholinergic neurotransmission, a subsequent increase in cortical APP involving PKCepsilon leads to accelerated amyloidogenic APP metabolism. The linkage of cholinergic activation and APP metabolism completes an additional feedback loop wherein the damage wrought by Abeta accelerates further Abeta production. A comprehensive vision of the neuropathophysiologic mechanisms that result in AD reveals several vicious cycles within a larger vicious cycle, that is to say, a number of interactive systems that each, once set in motion, amplify their own processes, thus accelerating the development of AD.

Small heat shock protein HspB8: its distribution in Alzheimer’s disease brains and its inhibition of amyloid-β protein aggregation and cerebrovascular amyloid-β toxicity

Alzheimer's disease (AD) is characterized by pathological lesions, such as senile plaques (SPs) and cerebral amyloid angiopathy (CAA), both predominantly consisting of a proteolytic cleavage product of the amyloid-beta precursor protein (APP), the amyloid-beta peptide (Abeta). CAA is also the major pathological lesion in hereditary cerebral hemorrhage with amyloidosis of the Dutch type (HCHWA-D), caused by a mutation in the gene coding for the Abeta peptide. Several members of the small heat shock protein (sHsp) family, such as alphaB-crystallin, Hsp27, Hsp20 and HspB2, are associated with the pathological lesions of AD, and the direct interaction between sHsps and Abeta has been demonstrated in vitro. HspB8, also named Hsp22 of H11, is a recently discovered member of the sHsp family, which has chaperone activity and is observed in neuronal tissue. Furthermore, HspB8 affects protein aggregation, which has been shown by its ability to prevent formation of mutant huntingtin aggregates. The aim of this study was to investigate whether HspB8 is associated with the pathological lesions of AD and HCHWA-D and whether there are effects of HspB8 on Abeta aggregation and Abeta-mediated cytotoxicity. We observed the expression of HspB8 in classic SPs in AD brains. In addition, HspB8 was found in CAA in HCHWA-D brains, but not in AD brains. Direct interaction of HspB8 with Abeta(1-42), Abeta(1-40) and Abeta(1-40) with the Dutch mutation was demonstrated by surface plasmon resonance. Furthermore, co-incubation of HspB8 with D-Abeta(1-40) resulted in the complete inhibition of D-Abeta(1-40)-mediated death of cerebrovascular cells, likely mediated by a reduction in both the beta-sheet formation of D-Abeta(1-40) and its accumulation at the cell surface. In contrast, however, with Abeta(1-42), HspB8 neither affected beta-sheet formation nor Abeta-mediated cell death. We conclude that HspB8 might play an important role in regulating Abeta aggregation and, therefore, the development of classic SPs in AD and CAA in HCHWA-D.

Glypican-1 as an Abeta binding HSPG in the human brain: its localization in DIG domains and possible roles in the pathogenesis of Alzheimer's disease.

Previous studies have suggested that heparan sulfate proteoglycans (HSPGs) play a role in deposition of beta-amyloid protein (Abeta) in the Alzheimer's disease (AD) brain. In the present study, we demonstrated that glypican-1 can bind fibrillar Abeta, and the binding is mainly mediated by heparan sulfate (HS) chains. Further analysis revealed that glypican-1 is the major HSPG localized in detergent-insoluble glycosphingolipid-enriched (DIG) domains where all machineries for Abeta production exist and Abeta is accumulated as monomeric and oligomeric forms. Immunohistochemical studies demonstrated that glypican-1 is localized in primitive plaques as well as classic plaques. Moreover, overexpression of glypican-1 and amyloid precursor protein in SH-SY5Y cells resulted in reduced cell viability and made cells more susceptible to thapsigargin-induced stress and Abeta toxicity. The results raise the possibility that glypican-1 interacts with oligomerized or polymerized Abeta in such a specific compartment as DIG, resulting not only in amyloid deposition in senile plaques of AD brain, but also in accelerating neuronal cell death in response to stress and Abeta.

Synthesis, aggregation, neurotoxicity, and secondary structure of various A [formula omitted]1–42 mutants of familial Alzheimer's disease at positions 21–23

Cerebral amyloid angiopathy (CAA) due to amyloid β (Aβ) deposition is a key pathological feature of Alzheimer's disease (AD), especially in some form of familial Alzheimer's disease (FAD) including hereditary cerebral hemorrhage with amyloidosis—Dutch type. Aβ mainly consists of 40- and 42-mer peptides (Aβ1–40 and Aβ1–42), which accumulate in senile plaques of AD brains and show neurotoxicity for cultured nerve cells. We synthesized all variant forms of Aβ1–42 associated with reported FAD, such as A21G (Flemish), E22Q (Dutch), E22K (Italian), E22G (Arctic), and D23N (Iowa) along with three potential mutants by one point missense mutation (E22A, E22D, and E22V) in a highly pure form, and examined their ability to aggregate and their neurotoxicity in PC12 cells. The mutants at positions 22 and 23 showed potent aggregative ability and neurotoxicity whereas the potential mutants did not, indicating that Aβ1–42 mutants at positions 22 and 23 play a critical role in FAD of Dutch-, Italian-, Arctic-, and Iowa-types. However, Flemish-type FAD needs alternative explanation except the aggregation and neurotoxicity of the corresponding Aβ1–42 mutant.

Hemisynaptic distribution patterns of presenilins and β‐APP isoforms in the rodent cerebellum and hippocampus

Healthy brain neurons co-express Alzheimer's disease (AD) related proteins presenilins (PS) and β-amyloid precursor protein (β-APP). Deposition of β-amyloid and PS in the senile plaques of AD brain and their ability to interact in vitro suggest that AD pathology could arise from a defect in the physiological interactions between β-APP and PS within and/or between neurons. The present study compares the immunocytochemical distribution of PS (1 and 2) and β-APP major isoforms (695 and 751/770) in the synapses of the cerebellum and hippocampus of the adult rat and mouse. In the cerebellar cortex of both species, the four molecules are immunodetected in the presynaptic or the postsynaptic compartments of synapses, suggesting that they are involved in interneuronal relationships. In contrast, PS and β-APP are postsynaptic in almost all the immunoreactive synapses of the hippocampus. The different distribution patterns of these proteins in cerebellar and hippocampal synapses may reflect specific physiological differences, responsible for differential vulnerability of neurons to AD synaptic pathology. Defective interactions between β-APP and PS at the synapses could impede the synaptic functions of β-APP, inducing the selective loss of synapses that accounts for cognitive impairment in AD. Synapse 35:96–110, 2000. © 2000 Wiley-Liss, Inc.

Hemisynaptic distribution patterns of presenilins and beta-APP isoforms in the rodent cerebellum and hippocampus.

Healthy brain neurons co-express Alzheimer's disease (AD) related proteins presenilins (PS) and beta-amyloid precursor protein (beta-APP). Deposition of beta-amyloid and PS in the senile plaques of AD brain and their ability to interact in vitro suggest that AD pathology could arise from a defect in the physiological interactions between beta-APP and PS within and/or between neurons. The present study compares the immunocytochemical distribution of PS (1 and 2) and beta-APP major isoforms (695 and 751/770) in the synapses of the cerebellum and hippocampus of the adult rat and mouse. In the cerebellar cortex of both species, the four molecules are immunodetected in the presynaptic or the postsynaptic compartments of synapses, suggesting that they are involved in interneuronal relationships. In contrast, PS and beta-APP are postsynaptic in almost all the immunoreactive synapses of the hippocampus. The different distribution patterns of these proteins in cerebellar and hippocampal synapses may reflect specific physiological differences, responsible for differential vulnerability of neurons to AD synaptic pathology. Defective interactions between beta-APP and PS at the synapses could impede the synaptic functions of beta-APP, inducing the selective loss of synapses that accounts for cognitive impairment in AD.

Elevated oxidative stress in models of normal brain aging and Alzheimer's disease

Age-associated neurodegenerative disorders are becoming more prevalent as the mean age of the population increases in the United States over the next few decades. Both normal brain aging and Alzheimer's disease (AD) are associated with oxidative stress. Our laboratory has used a wide variety of physical and biochemical methods to investigate free radical oxidative stress in several models of aging and AD. β-amyloid (Aβ), the peptide that constitutes the central core of senile plaques in AD brain, is associated with free radical oxidative stress and is toxic to neurons. This review summarizes some of our studies in aging and Aβ-associated free radical oxidative stress and on the modulating effects of free radical scavengers on neocortical synaptosomal membrane damage found in aging and Aβ-treated systems.

The complement cascade In Alzheimer's disease

Numerous studies show that activated glial cells release increased amounts of several molecules that might contribute to the pathology of Alzheimer's disease (AD), including complement proteins. The complement proteins are particularly noteworthy because of their well-documented ability to induce inflammation, destroy foreign cells and, in certain circumstances, inflict damage to host tissue. There appears to be a general consensus that the early components of the classical complement pathway are found associated with senile plaques in AD brain; of some dispute is whether the later complement products are truly found in AD brain. An unequivocal demonstration of the terminal complement activation products in AD brain is important in strengthening the hypothesis that these products contribute to disease pathology. To date, it has been difficult to determine the extent to which complement activation contributes to the neuropathology of AD. Given the potential detrimental consequences of complement activation in AD brain, there is compelling reason to identify potential therapeutic agents that might attenuate complement activity in this disease. Based on the evidence that Abeta is a likely activator of complement in AD, and on the understanding of the nature of Abeta-C1q binding, it is possible that drugs might be developed that will slow complement activity in the AD brain without compromising this defense mechanism throughout the rest of the body.

Specific increase in amyloid beta-protein 42 secretion ratio by calpain inhibition.

Cerebral deposition of amyloid beta-protein (Abeta) as senile plaques is a pathological hallmark of Alzheimer's disease (AD). Abeta falls into two major subspecies defined by their C-termini, Abeta40 and Abeta42, ending in Val-40 and Ala-42, respectively. Although Abeta42 accounts for only approximately 10% of secreted Abeta, Abeta42 is the predominant species accumulated in senile plaques in AD brain and appears to be the initially deposited species. Its secretion level has recently been reported to be increased in the plasma or culture media of fibroblasts from patients affected by any of early-onset familial AD (FAD). Thus, inhibition of Abeta42 production would be one of the therapeutic targets for AD. However, there is little information about the cleavage mechanism via which Abeta40 and Abeta42 are generated and its relationship to intracellular protease activity. Here, we examined by well-characterized enzyme immunoassay the effects of calpain and proteasome inhibitors on the levels of Abeta40 and Abeta42 secretion by cultured cells. A calpastatin peptide homologous to the inhibitory domain of calpastatin, an endogenous calpain specific inhibitor, induced a specific increase in secreted Abeta42 relative to the total secreted Abeta level, a characteristic of the cultured cells transfected with FAD-linked mutated genes, while a proteasome specific inhibitor, lactacystin, showed no such effect. These findings suggest that the Abeta42 secretion ratio is modulated by the calpain-calpastatin system and may point to the possibility of exploring particular compounds that inhibit Abeta42 secretion through this pathway.