BACKGROUND The order and magnitude of pathologic processes in Alzheimer’s disease are not well understood, partly because the disease develops over many years. Autosomal dominant Alzheimer’s disease has a predictable age at onset and provides an opportunity to determine the sequence and magnitude of pathologic changes that culminate in symptomatic disease. METHODS In this prospective, longitudinal study, we analyzed data from 128 participants who underwent baseline clinical and cognitive assessments, brain imaging, and cerebrospinal fluid (CSF) and blood tests. We used the participant’s age at baseline assessment and the parent’s age at the onset of symptoms of Alzheimer’s disease to calculate the estimated years from expected symptom onset (age of the participant minus parent’s age at symptom onset). We conducted cross-sectional analyses of baseline data in relation to estimated years from expected symptom onset in order to determine the relative order and magnitude of pathophysiological changes. RESULTS Concentrations of amyloid-beta (Aβ)42 in the CSF appeared to decline 25 years before expected symptom onset. Aβ deposition, as measured by positron-emission tomography with the use of Pittsburgh compound B, was detected 15 years before expected symptom onset. Increased concentrations of tau protein in the CSF and an increase in brain atrophy were detected 15 years before expected symptom onset. Cerebral hypometabolism and impaired episodic memory were observed 10 years before expected symptom onset. Global cognitive impairment, as measured by the Mini–Mental State Examination and the Clinical Dementia Rating scale, was detected 5 years before expected symptom onset, and patients met diagnostic criteria for dementia at an average of 3 years after expected symptom onset. CONCLUSIONS We found that autosomal dominant Alzheimer’s disease was associated with a series of pathophysiological changes over decades in CSF biochemical markers of Alzheimer’s disease, brain amyloid deposition, and brain metabolism as well as progressive cognitive impairment. Our results require confirmation with the use of longitudinal data and may not apply to patients with sporadic Alzheimer’s disease. (Funded by the National Institute on Aging and others; DIAN ClinicalTrials.gov number, NCT00869817.)
We have purified and characterized the cerebral amyloid protein that forms the plaque core in Alzheimer disease and in aged individuals with Down syndrome. The protein consists of multimeric aggregates of a polypeptide of about 40 residues (4 kDa). The amino acid composition, molecular mass, and NH2-terminal sequence of this amyloid protein are almost identical to those described for the amyloid deposited in the congophilic angiopathy of Alzheimer disease and Down syndrome, but the plaque core proteins have ragged NH2 termini. The shared 4-kDa subunit indicates a common origin for the amyloids of the plaque core and of the congophilic angiopathy. There are superficial resemblances between the solubility characteristics of the plaque core and some of the properties of scrapie infectivity, but there are no similarities in amino acid sequences between the plaque core and scrapie polypeptides.There are several closely associated morphologic changes in the brains of individuals with Alzheimer disease (AD): neurofibrillary tangles (NFTs) within neurons; plaques consisting of various proportions of amyloid cores (APCs) § surrounded by neuritic degeneration; a variable degree of congophilic angiopathy (ACA); and widespread neuronal loss and gliosis in areas affected by NFTs and plaque formation. The composition of the NFT is still in doubt due in part to the difficulty in achieving complete solubilization (2).Little is known about the pathogenesis of the APC, particularly whether the amyloid core precedes or proceeds from the surrounding neuritic degeneration. Since the amyloid plaque also occurs in some of the unconventional virus infections (3), and because recent data have drawn attention to the similarities between amyloid fibrils and the infectious agent of scrapie (4), speculation has naturally increased over the possible infectious nature of amyloid in AD. As a direct approach to unraveling the pathogenesis of the AD plaque, we have isolated and purified the amyloid from the cores of the plaques. For comparison, we have also studied the APC from the brains of an aged individual with Down syndrome (DS), in which the typical changes of AD also occur. MATERIALS AND METHODSSelection of Samples. For AD and DS cases, at the time of autopsy, one half of the brain was frozen at -70°C and the remaining half was fixed in Formalin for subsequent histological confirmation. Control brain samples were taken from individuals in whom there was no histological evidence of APC or NFT.Isolation and Purification of APCs. The frozen hemisphere is partially thawed and sliced at 1-cm intervals. The cortical grey matter is collected for homogenization (Sorvall Omnimixer) in buffer 1 (10 mM Tris HCl/150 mM NaCl/5 mM EDTA/1% Triton-X 100/0.4 mM phenylmethylsulfonyl fluoride, pH 7.2) at a sample-to-buffer ratio of 1:9 (wt/vol). This homogenate is stirred on ice for 10 min, then centrifuged at 10,000 x g for 20 min (Sorvall RC2-B, GSA rotor, 40C). The supernatant is discarded and the pellet is extracted with stirring for 20 min on i...
Alzheimer's disease is characterized by a widespread functional disturbance of the human brain. Fibrillar amyloid proteins are deposited inside neurons as neurofibrillary tangles and extracellularly as amyloid plaque cores and in blood vessels. The major protein subunit (A4) of the amyloid fibril of tangles, plaques and blood vessel deposits is an insoluble, highly aggregating small polypeptide of relative molecular mass 4,500. The same polypeptide is also deposited in the brains of aged individuals with trisomy 21 (Down's syndrome). We have argued previously that the A4 protein is of neuronal origin and is the cleavage product of a larger precursor protein. To identify this precursor, we have now isolated and sequenced an apparently full-length complementary DNA clone coding for the A4 polypeptide. The predicted precursor consists of 695 residues and contains features characteristic of glycosylated cell-surface receptors. This sequence, together with the localization of its gene on chromosome 21, suggests that the cerebral amyloid deposited in Alzheimer's disease and aged Down's syndrome is caused by aberrant catabolism of a cell-surface receptor.
Oxidative stress has been implicated in the progression of Alzheimer's disease, Parkinson's disease and amyotrophic lateral sclerosis. Oxygen is vital for life but is also potentially dangerous, and a complex system of checks and balances exists for utilizing this essential element. Oxidative stress is the result of an imbalance in pro-oxidant/antioxidant homeostasis that leads to the generation of toxic reactive oxygen species. The systems in place to cope with the biochemistry of oxygen are complex, and many questions about the mechanisms of oxygen regulation remain unanswered. However, this same complexity provides a number of therapeutic targets, and different strategies, including novel metal-protein attenuating compounds, aimed at a variety of targets have shown promise in clinical studies.
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