Alzheimer's disease and control brain contain soluble derivatives of the amyloid protein precursor that end within the beta amyloid protein region.

The 39-43 amino acid beta amyloid protein (A beta) that deposits as amyloid in the brains of patients with Alzheimer's disease (AD) is encoded as an internal sequence within a larger membrane-associated protein known as the amyloid protein precursor (APP). In cultured cells, the APP is normally cleaved within the A beta to generate a large secreted derivative and a small membrane-associated fragment. Neither of these derivatives can produce amyloid because neither contains the entire A beta. Our study was designed to determine whether the soluble APP derivatives in human brain end within the A beta as described in cell culture or whether AD brain produces potentially amyloidogenic soluble derivatives that contain the entire A beta. We find that both AD and control brain contain nonamyloidogenic soluble derivatives that end at position 15 of the A beta. We have been unable to detect any soluble derivatives that contain the entire A beta in either the AD or control brain.     

Stereochemical specificity of Alzheimer's disease beta-peptide assembly

The formation and growth of insoluble amyloid deposits composed primarily of the human beta-amyloid peptide (A beta) in brain is an essentially invariant feature of Alzheimer's disease (AD) and is widely believed to contribute to the progressive neurodegeneration of the disorder. To probe the specificity of amyloid formation and growth, we synthesized and examined the self-assembly of D- and L-stereoisomers of A beta in vitro. While both enantiomers formed insoluble aggregates at similar rates with amyloid-like fibrillar morphology, deposition of soluble A beta peptide onto preexisting A beta aggregates was stereospecific. Although the L-peptide deposited readily onto immobilized L-A beta aggregates with first-order kinetic dependence on soluble peptide concentration, essentially no association between the D-peptide and L-template was observed. Similarly, the D-peptide deposited with first-order kinetics onto a D-A beta aggregate template but did not deposit onto a similar template composed of aggregates of the L-enantiomer. Furthermore, although the L-A beta isomer deposited onto authentic AD amyloid in preparations of unfixed AD brain, no focal association between the D-peptide and brain amyloid was detected. These results establish that deposition of soluble A beta onto preexisting amyloid template is stereospecific, likely involving direct docking interactions between peptide backbone and/or side chains rather than simple hydrophobic association.     

P2Y receptors in Alzheimer's disease

Alzheimer's disease (AD) is the most common cause of dementia, affecting more than 10% of people over the age of 65. Age is the greatest risk factor for AD, although a combination of genetic, lifestyle and environmental factors also contribute to disease development. Common features of AD are the formation of plaques composed of beta‐amyloid peptides (Aβ) and neuronal death in brain regions involved in learning and memory. Although Aβ is neurotoxic, the primary mechanisms by which Aβ affects AD development remain uncertain and controversial. Mouse models overexpressing amyloid precursor protein and Aβ have revealed that Aβ has potent effects on neuroinflammation and cerebral blood flow that contribute to AD progression. Therefore, it is important to consider how endogenous signalling in the brain responds to Aβ and contributes to AD pathology. In recent years, Aβ has been shown to affect ATP release from brain and blood cells and alter the expression of G protein‐coupled P2Y receptors that respond to ATP and other nucleotides. Accumulating evidence reveals a prominent role for P2Y receptors in AD pathology, including Aβ production and elimination, neuroinflammation, neuronal function and cerebral blood flow.     

Amyloid beta.

Amyloid beta (A beta) is a 39-43 residue amyloidogenic peptide that is deposited into the extracellular amyloid plaques which characterize an Alzheimer's disease (AD) brain. A beta is derived from the amyloid precursor protein (APP) and undergoes a toxic conformational change (gain of toxic function). The length of the A beta peptide dramatically influences its properties with the longer 42 and 43 residue species being more amyloidogenic. The genetics of familial AD (FAD) supports a central role for A beta in AD since mutations in the FAD causing genes APP and the presenilins (PS1 and PS2) increase the formation of A beta 42,43. Considerable activity is directed towards A beta as a therapeutic target. These strategies aim to inhibit A beta synthesis, A beta fibril formation, its toxic actions on cells or promote its clearance from the brain.     

Alzheimer's disease therapeutics: new approaches to an ageing problem

Abnormal proteinaceous deposits are found in the brain of patients with many different neurodegenerative diseases. In many of these diseases, the production of the deposits is probably associated with disease pathogenesis. In Alzheimer's disease (AD), the amyloid protein (A beta), is produced by the action of enzymes known as secretases, which cleave the beta-amyloid protein precursor. A beta is secreted from cells in the brain, after which it oligomerizes and is deposited in the extracellular compartment of the brain to form amyloid plaques and amyloid angiopathy. Targeting the production of A beta and its aggregation is now a key strategy in the development of novel therapeutic agents for the treatment of AD. This review examines the potential of immunization strategies, cholesterol-lowering drugs, protease inhibitors and nicotinic drugs for the treatment of AD.     

Noninvasive imaging of peripherally injected Alzheimer's disease type synthetic A beta amyloid in vivo

The pathological hallmark of Alzheimer's disease (AD) is accumulation in the brain of amyloid composed of the 40-mer peptide A beta. Many fundamental questions about the biology of (AD) remain unanswered because there is currently no method of quantifying A beta amyloid in vivo. A noninvasive method of detecting and quantifying A beta amyloid in vivo would have wide application for the premortem diagnosis of AD and the efficient evaluation of candidate therapeutics aimed at inhibiting the formation and growth of A beta amyloid. Taking advantage of the extraordinarily high affinity of A beta for itself, we have synthesized an N'-terminal diethylenetriaminepentaacetic acid (DTPA) derivative of A beta possessing the kinetic activity and specificity for A beta amyloid desired of a probe to be used for noninvasive imaging. DTPA-A beta(3-40) is readily labeled with (111)InOAc(3) to yield a stable probe with exquisite specificity for naturally occurring and synthetic A beta amyloid in vitro. Moreover, (111)In-DTPA-A beta(3-40), administered intravascularly can specifically deposit onto and label previously injected synthetic A beta amyloid and be imaged in vivo with a gamma camera. The present results demonstrate the design, synthesis, and use of an A beta amyloid-specific probe and methods for its use as a noninvasive imaging agent. In vivo imaging of A beta amyloid represents an important step toward the development of biochemically based objective tools for the assessment of progression of AD and efficacy of potential therapeutics.     

Mass spectrometry of purified amyloid beta protein in Alzheimer's disease.

The amyloid beta-protein (A beta) that is progressively deposited in Alzheimer's disease (AD) arises from proteolysis of the integral membrane protein, beta-amyloid precursor protein (beta APP). Although A beta formation appears to play a seminal role in AD, only a few studies have examined the chemical structure of A beta purified from brain, and there are discrepancies among the findings. We describe a new method for the rapid extraction and purification of A beta that minimizes artifactual proteolysis. A beta purified by two-dimensional reverse-phase HPLC was analyzed by combined amino acid sequencing and mass spectrometry after digestion with a lysylendopeptidase. The major A beta peptide in the cerebral cortex of all five AD brains examined was aspartic acid 1 to valine 40. A minor species beginning at glutamic acid 3 but blocked by conversion to pyroglutamate was also found in all cases. A species ending at threonine 43 was detected, varying from approximately 5 to 25% of total A beta COOH-terminal fragments. Peptides ending with valine 39, isoleucine 41, or alanine 42 were not detected, except for one brain with a minor peptide ending at valine 39. Our findings suggest that A beta 1-40 is the major species of beta-protein in AD cerebral cortex. A beta 1-40 and A beta 1-43 peptides could arise independently from beta APP, or A beta 1-43 could be the initial excised fragment, followed by digestion to yield A beta 1-40. These analyses of native A beta in AD brain recommend the use of synthetic A beta 1-40 peptide to model amyloid fibrillogenesis and toxicity in vitro.     

雌激素对淀粉样β蛋白代谢的调节和毒性缓解

以淀粉样β蛋白为主的老年斑胞外沉积和神经元内神经原纤维缠结,是阿尔采末病(AD)特征性的病理学改变。近来,人们逐渐认可淀粉样蛋白假说,即认为淀粉样蛋白沉积是AD最初起因。研究人员正在寻找针对淀粉样β蛋白沉积的药物,雌激素是其中之一。初步的工作证明,雌激素能够调节淀粉样β蛋白前体代谢,减少淀粉样β蛋白生成,也能够减轻淀粉样B蛋白引起的免疫炎症反应、氧应激对细胞造成的损伤,和对抗细胞凋亡。     

Detection of amyloid beta protein precursor immunoreactivity in normal and Alzheimer's disease cerebrospinal fluid

The amyloid A4 (or beta protein), a 4.2 kD polypeptide, is a major component of amyloid deposits in the brains of patients with Alzheimer's Disease (AD). The self-aggregating amyloid A4 protein of AD is encoded as part of three larger proteins by the amyloid A4 precursor gene. The corresponding proteins have 695, 751 and 770 amino acid residues. To investigate the utility of amyloid beta protein precursor (A beta PP) as a diagnostic marker for AD an antiserum against a synthetic peptide (175-186), predicted from cDNA sequence for A beta PP, was used. The immunoreactivity of A beta PP in normal and AD cerebrospinal fluid (CSF) was measured by Western blot and detected with radiolabeled protein A. A total of fifty-seven CSF samples (AD = 27 and normal = 30) were analyzed for A beta PP immunoreactivity. A polyclonal antibody detected two major protein bands with apparent molecular weights of 105kD and 90kD both in normal and AD CSF. The difference between normal and AD CSF was not significant. These results indicate that immunoreactivity of A beta PP is present both in normal and AD CSF, and that the difference is too small to be used as a diagnostic marker.     

Links Between the Pathology of Alzheimer's Disease and Vascular Dementia

The major neuropathological lesions defining Alzheimer's disease (AD) include neurofibrillary tangles and amyloid plaques, which are mainly composed of abnormally phosphorylated tau and amyloid-beta (A beta), respectively. Numerous neuropathological and neuroimaging studies indicate that at least one-third of AD cases are complicated by some degree of vascular pathology, whereas in a similar proportion of patients clinically diagnosed with vascular dementia, AD pathology is also present. Many classical vascular risk factors such as hypertension, diabetes mellitus, and hypercholesterolemia have recently been shown also to increase the risk of AD. Growing evidence suggests that vascular pathology lowers the threshold for the clinical presentation of dementia at a given level of AD-related pathology and potentially directly promotes AD lesions such as A beta plaques. Cerebral ischemia, chronically up-regulates expression of the amyloid precursor protein (APP), which is the precursor to the amyloid beta peptide and damages the blood-brain barrier (BBB), affecting A beta peptide clearance from the brain. Recognition of the importance of these vascular risk factors for AD-related dementia and their treatment will be beneficial not only for preventing cardiac, cerebral, and peripheral complications of vascular disease, but also will likely have a direct impact on the occurrence of sporadic AD in older subjects. In this paper, we review some of the links between vascular risk factors and AD pathology and present data on the direct effect of ischemia on cognitive function and A beta deposition in a mouse model of AD.     

Melatonin increases survival and inhibits oxidative and amyloid pathology in a transgenic model of Alzheimer's disease

Increased levels of a 40-42 amino-acid peptide called the amyloid beta protein (A beta) and evidence of oxidative damage are early neuropathological markers of Alzheimer's disease (AD). Previous investigations have demonstrated that melatonin is decreased during the aging process and that patients with AD have more profound reductions of this hormone. It has also been recently shown that melatonin protects neuronal cells from A beta-mediated oxidative damage and inhibits the formation of amyloid fibrils in vitro. However, a direct relationship between melatonin and the biochemical pathology of AD had not been demonstrated. We used a transgenic mouse model of Alzheimer's amyloidosis and monitored over time the effects of administering melatonin on brain levels of A beta, abnormal protein nitration, and survival of the mice. We report here that administration of melatonin partially inhibited the expected time-dependent elevation of beta-amyloid, reduced abnormal nitration of proteins, and increased survival in the treated transgenic mice. These findings may bear relevance to the pathogenesis and therapy of AD.     

综述:脑衰老与阿尔茨海默病症状出现前阶段

脑衰老可分为生理性增龄变化与病理性变化,后者与阿尔茨海默病(Alzheimer's disease,AD)等神经退行性疾病的发生有关．生理性脑衰老与AD在发病早期具有相似的表现形式、病变特征、生化改变和发病机制．其共同的分子机制是异常蛋白质蓄积,提示两者有着相似的病理学基础,脑衰老可能是AD等神经退行性改变的最初级阶段,病理性脑衰老因素可能促进AD等神经退行性疾病的发生发展．临床前期AD(preclinical AD,PCAD)患者的脑、血液和脑脊液中可以检测到AD特定的生物标记物,但AD的临床症状并没有出现,因此也被称为“症状出现前AD(presymptomatic AD)”．PCAD和对照组比较,氧化应激指标和高度不溶性Aβ42并没有显著性升高,寻找早期PCAD发病过程中新的可用于临床早期诊断的生物标记物、药物靶点将成为我们的关注重点．     

How chronic inflammation can affect the brain and support the development of Alzheimer's disease in old age: the role of microglia and astrocytes

A huge amount of evidence has implicated amyloid beta (A beta) peptides and other derivatives of the amyloid precursor protein (beta APP) as central to the pathogenesis of Alzheimer's disease (AD). It is also widely recognized that age is the most important risk factor for AD and that the innate immune system plays a role in the development of neurodegeneration. Little is known, however, about the molecular mechanisms that underlie age-related changes of innate immunity and how they affect brain pathology. Aging is characteristically accompanied by a shift within innate immunity towards a pro-inflammatory status. Pro-inflammatory mediators such as tumour necrosis factor-alpha or interleukin-1 beta can then in combination with interferon-gamma be toxic on neurons and affect the metabolism of beta APP such that increased concentrations of amyloidogenic peptides are produced by neuronal cells as well as by astrocytes. A disturbed balance between the production and the degradation of A beta can trigger chronic inflammatory processes in microglial cells and astrocytes and thus initiate a vicious circle. This leads to a perpetuation of the disease.     

Differential accumulation of soluble amyloid β peptides 1–40 and 1–42 in human monocytic and neuroblastoma cell lines

Alzheimer's disease (AD) is characterized by the massive deposition in the brain of the 40-42-residue amyloid beta protein (A(beta)). While A(beta)1-40 predominates in the vascular system, A(beta)1-42 is the major component of the senile plaques in the neuropil. The concentration of both A(beta) species required to form amyloid fibrils in vitro is micromolar, yet soluble A(betas) found in normal and AD brains are in the low nanomolar range. It has been recently proposed that the levels of A(beta) sufficient to trigger amyloidogenesis may be reached intracellularly. To study the internalization and intracellular accumulation of the major isoforms of A(beta), we used THP-1 and IMR-32 neuroblastoma cells as models of human monocytic and/or macrophagic and neuronal lineages, respectively. We tested whether these cells were able to internalize and accumulate 125I-A(beta)1-40 and 125I-A(beta)1-42 differentially when offered at nanomolar concentrations and free of large aggregates, conditions that mimic a prefibrillar stage of A(beta) in AD brain. Our results showed that THP-1 monocytic cells internalized at least 10 times more 125I-A(betas) than IMR-32 neuroblastoma cells, either isolated or in a coculture system. Moreover, 125I-A(beta)1-42 presented a higher adsorption, internalization, and accumulation of undigested peptide inside cells, as opposed to 125I-A(beta)1-40. These results support that A(beta)1-42, the major pathogenic form in AD, may reach supersaturation and generate competent nuclei for amyloid fibril formation intracellularly. In light of the recently reported strong neurotoxicity of soluble, nonfibrillar A(beta)1-42, we propose that intracellular amyloidogenesis in microglia is a protective mechanism that may delay neurodegeneration at early stages of the disease.     

The evolution of A beta peptide burden in the APP23 transgenic mice: implications for A beta deposition in Alzheimer disease.

BACKGROUND: High levels of A beta in the cerebral cortex distinguish demented Alzheimer's disease (AD) from nondemented elderly individuals, suggesting that decreased amyloid-beta (A beta) peptide clearance from the brain is a key precipitating factor in AD. MATERIALS AND METHODS: The levels of A beta in brain and plasma as well as apolipoprotein E (ApoE) in brain were investigated by enzyme-linked immunosorbent assay (ELISA) and Western blotting at various times during the life span of the APP23 transgenic (Tg) and control mice. Histochemistry and immunocytochemistry were used to assess the morphologic characteristics of the brain parenchymal and cerebrovascular amyloid deposits and the intracellular amyloid precursor protein (APP) deposits in the APP23 Tg mice. RESULTS: No significant differences were found in the plasma levels of A beta between the APP23 Tg and control mice from 2-20 months of age. In contrast, soluble A beta levels in the brain were continually elevated, increasing 4-fold at 2 months and 33-fold in the APP23 Tg mice at 20 months of age when compared to the control mice. Soluble A beta42 was about 60% higher than A beta40. In the APP23 Tg mice, insoluble A beta40 remained at basal levels in the brain until 9 months and then rose to 680 microg/g cortex by 20 months. Insoluble A beta40 was negligible in non-Tg mice at all ages. Insoluble A beta42 in APP23 Tg mice rose to 60 microg/g cortex at 20 months, representing 24 times the control A beta42 levels. Elevated levels of ApoE in the brain were observed in the APP23 Tg mice at 2 months of age, becoming substantially higher by 20 months. ApoE colocalized with A beta in the plaques. Beta-amyloid precursor protein (betaAPP) deposits were detected within the neuronal cytoplasm from 4 months of age onward. Amyloid angiopathy in the APP23 Tg mice increased markedly with age, being by far more severe than in the Tg2576 mice. CONCLUSIONS: We suggest that the APP23 Tg mouse may develop an earlier blockage in A beta clearance than the Tg2576 mice, resulting in a more severe accumulation of A beta in the perivascular drainage pathways and in the brain. Both Tg mice reflect decreased A beta elimination and as models for the amyloid cascade they are useful to study AD pathophysiology and therapy.     

Human amyloid-beta causes changes in the levels of endothelial protein kinase C and its alpha isoform in vitro

Amyloid-beta (A(beta)) deposits and neurofibrillary pathology are characteristic features of Alzheimer's disease (AD). The association of A(beta) with cerebral vessels is an intriguing feature of AD. While there is considerable evidence of altered activities of the major isoforms of protein kinase C (PKC) in the vasculature and neurons of AD brains, little is known about the relationship between the Abeta toxicity and the altered PKC levels in cerebral endothelial cells.In this study, cultured brain endothelial cells exposed to A(beta)1-40 revealed a translocation of PKC from the membrane fraction to the cytosol. The content of the isoform PKC(alpha), involved in the regulation of amyloid precursor protein (APP) secretion, was decreased in the membrane-bound fraction of rat endothelial cells and increased in the cytosol after A(beta)1-40 treatment. These data suggest that the accumulation of A(beta) peptide in the cerebral vasculature may play a significant role in the down-regulation of PKC seen in the AD cerebral vasculature.     

Mechanisms of A beta mediated neurodegeneration in Alzheimer's disease

Development of a comprehensive therapeutic treatment for the neurodegenerative Alzheimer's disease (AD) is limited by our understanding of the underlying biochemical mechanisms that drive neuronal failure. Numerous dysfunctional mechanisms have been described in AD, ranging from protein aggregation and oxidative stress to biometal dyshomeostasis and mitochondrial failure. In this review we discuss the critical role of amyloid-beta (A beta) in some of these potential mechanisms of neurodegeneration. The 39-43 amino acid A beta peptide has attracted intense research focus since it was identified as a major constituent of the amyloid deposits that characterise the AD brain, and it is now widely recognised as central to the development of AD. Familial forms of AD involve mutations that lead directly to altered A beta production from the amyloid-beta A4 precursor protein, and the degree of AD severity correlates with specific pools of A beta within the brain. A beta contributes directly to oxidative stress, mitochondrial dysfunction, impaired synaptic transmission, the disruption of membrane integrity, and impaired axonal transport. Further study of the mechanisms of A beta mediated neurodegeneration will considerably improve our understanding of AD, and may provide fundamental insights needed for the development of more effective therapeutic strategies.     

The Alzheimer's disease mitochondrial cascade hypothesis: Progress and perspectives

Ten years ago we first proposed the Alzheimer's disease (AD) mitochondrial cascade hypothesis. This hypothesis maintains that gene inheritance defines an individual's baseline mitochondrial function; inherited and environmental factors determine rates at which mitochondrial function changes over time; and baseline mitochondrial function and mitochondrial change rates influence AD chronology. Our hypothesis unequivocally states in sporadic, late-onset AD, mitochondrial function affects amyloid precursor protein (APP) expression, APP processing, or beta amyloid (Aβ) accumulation and argues if an amyloid cascade truly exists, mitochondrial function triggers it. We now review the state of the mitochondrial cascade hypothesis, and discuss it in the context of recent AD biomarker studies, diagnostic criteria, and clinical trials. Our hypothesis predicts that biomarker changes reflect brain aging, new AD definitions clinically stage brain aging, and removing brain Aβ at any point will marginally impact cognitive trajectories. Our hypothesis, therefore, offers unique perspective into what sporadic, late-onset AD is and how to best treat it. This article is part of a Special Issue entitled: Misfolded Proteins, Mitochondrial Dysfunction, and Neurodegenerative Diseases.     

Amyloid-beta-peptide reduces copper(II) to copper(I) independent of its aggregation state

Alzheimer's disease (AD) is characterized by the deposition of amyloid beta-peptide (A beta) and neuronal degeneration in brain regions involved in learning and memory. One of the leading etiologic hypotheses regarding AD is the involvement of free radical-mediated oxidative stress in neuronal degeneration. Recent evidence suggests that metals concentrated in amyloid deposits may contribute to the oxidative insults observed in AD-affected brains. We hypothesized that A beta peptide in the presence of copper enhances its neurotoxicity generating free radicals via copper reduction. In the present study, we have examined the effect of the aggregation state of amyloid-beta-peptide on copper reduction. In independent experiments we measured the copper-reducing ability of soluble and fibrillar A beta(1-40) forms by bathocuproine assays. As it was previously observed for the amyloid precursor protein (APP), the A beta peptide showed copper-reducing ability. The capacity of A beta to reduce copper was independent of the aggregation state. Finally, the A beta peptide derived from the human sequence has a greater effect than the A beta peptide derived from the rat sequence, suggesting that histidine 13 may play a role in copper reduction. In agreement with this possibility, the A beta peptide reduces less copper in the presence of exogenous histidine.