Faculty Bibliography

Amyloid beta (A beta) is a fibrillar component in Alzheimers' disease amyloid deposits and a soluble peptide (sA beta) normally present in body fluids. We have recently reported that the blood-brain barrier (BBB) has a capability to control cerebrovascular sequestration and transport of circulating sA beta. In this study, we examined whether two circulating amyloid-associated proteins shown to bind sA beta, apolipoproteins J (apo J) and E (apo E), can cross the BBB alone and/or complexed to a synthetic peptide homologous to a major form of sA beta, sA beta 1-40. Brain perfusion experiments in guinea pigs showed significant uptake of both apo J and sA beta 1-40-apo J complexes. In contrast, blood-brain transport of sA beta 1-40-apo E was negligible, while apo E had a limited access across the BBB, indicating that the apo E found within the brain is produced locally. It is concluded that sA beta 1-40 binding to apo J and apo E results in significant (> 100-fold) difference in brain uptake of their respective complexes. We hypothesize that in normal brain apo J facilitates sA beta transport

Numerous studies have established a linkage between the apolipoprotein (apo) E4 allele and late-onset Alzheimer's disease. It remains unclear if apo E plays a direct role in the pathogenesis of Alzheimer's disease and what, if any, are its significant interactions with amyloid beta (A beta) and tau. Apo E has been found immunohistochemically in all types of amyloid deposits and apo E fragments have been isolated from amyloid. Furthermore, apo E has been shown to bind soluble A beta. It has been proposed that apo E acts to promote and/or modulate A beta fibril formation. It is well established that peptides homologous to A beta will form amyloid-like fibrils in solution. With the use of electron microscopy and a thioflavin T assay for fibril formation we found that apo E and apo E4 in particular enhance this spontaneous fibrillogenesis of A beta peptides under the in vitro conditions used. These in vitro data suggest that the apo E4 isoform is a risk factor for Alzheimer's disease that acts to accelerate a process that can occur in its absence

Immunohistochemical and biochemical studies have demonstrated several different proteins in amyloid deposits that are not intrinsic components of the fibril itself but may play a role in their deposition and fibril formation. We compared the distribution of several amyloid-associated proteins, ie, amyloid P component, apolipoprotein-E, apolipoprotein-J, and vitronectin, in the deposits of several different amyloids, in particular light chain amyloid, with those in the deposits of nonamyloid monoclonal immunoglobulin, which may be considered a form of preamyloid disease. Although 100% of amyloid specimens (7 amyloid A, 15 immunoglobulin light chain, and 1 transthyretin) had amyloid P component and 100% had apolipoprotein-E (2 amyloid A, 10 immunoglobulin light chain, and 1 transthyretin) co-localized with the primary amyloid protein, none of the monoclonal nonamyloid cases (14 light chain deposition disease and 6 light and heavy chain deposition disease) had amyloid P component and only 1 of 11 had apolipoprotein-E. On the other hand, staining for apolipoprotein-J and vitronectin was positive in 100% of cases of amyloid and nonamyloid monoclonal deposits. The association between the presence of apolipoprotein-E and amyloid P component in the fibrillar form of monoclonal light chain deposits and their absence in the nonfibrillar form of deposits suggest a role for these proteins in the process of fibrillogenesis. This lends support for the previously proposed concept that apolipoprotein-E functions as a pathological chaperone by altering the conformation of amyloidogenic proteins

Late-onset and sporadic Alzheimer's disease are associated with the apolipoprotein E (apoE) type 4 allele expressing the protein isoform apoE4. Apolipoprotein E binds avidly to beta amyloid (A beta) peptide, a major component of senile plaque of Alzheimer's disease, in an isoform-specific manner. The apoE4 isoform binds to A beta peptide more rapidly than apoE3. We observed that soluble SDS-stable complexes of apoE3 or apoE4, formed by coincubation with A beta peptide, precipitated after several days of incubation at 37 degrees C with apoE4 complexes precipitating more rapidly than apoE3 complexes. A beta(1-28) and A beta(1-40) peptides were incubated in the presence or absence of apoE3, apoE4, or bovine serum albumin for 4 d at 37 degrees C (pH 7.3). Negative stain electron microscopy revealed that the A beta peptide alone self-assembled into twisted ribbons containing two or three strands but occasionally into multistranded sheets. The apoE/A beta coincubates yielded monofibrils 7 nm in diameter. ApoE4/A beta coincubates yielded a denser matrix of monofibrils than apoE3/A beta coincubates. Unlike purely monofibrillar apoE4/A beta coincubates, apoE3/A beta coincubates also contained double- and triple-stranded structures. Both apoE isoforms were shown by immunogold labeling to be uniformly distributed along the A beta peptide monofibrils. Monofibrils appeared earlier in apoE4/A beta than in apoE3/A beta in time-course experiments. Thus apoE3 and apoE4 each interact with beta amyloid peptide to form novel monofibrillar structures, apoE4 more avidly, a finding consistent with the biochemical and genetic association between apoE4 and Alzheimer's disease

The discovery of soluble amyloid beta (sA beta) suggests that the role of amyloid in Alzheimer's disease (AD) is similar to the previously studied systemic amyloidoses and alters the notion that membrane damage is the initial event in AD. The disease state is characterized by the abnormal accumulation of a normal degradative peptide, which becomes resistant to further proteolysis due to a conformational change. Mutations in the beta PP gene have been found in a very small percentage of AD cases; hence other factors, both genetic and environmental, need to be identified. Priority needs to be given to detailed studies of the structural differences between sA beta and the A beta in amyloid deposits. This will help uncover the determining factors governing the aggregation of sA beta. These structural alterations may be critical for the possible toxic effects A beta and/or associated proteins (molecular chaperones, e.g., apolipoprotein E) have on brain cell function

Apolipoprotein E (Apo E) has been shown to be closely associated with beta amyloid in Alzheimer's disease (AD) brain. In the present study, we have found strong Apo E immunoreactivity in the amyloid cores of senile plaques (SP) in the various brain regions examined. However, Apo E immunoreactivity in diffuse plaques varied distinctly and was strong within numerous cerebellar and cortical diffuse plaques, and absent or very weak within diffuse plaques in the striatum/thalamus. This distribution of Apo E immunoreactivity in SP correlates with the occurrence of small amounts of fibrillar amyloid in diffuse plaques that has been described in the cerebral and cerebellar cortex, but not in the basal ganglia. These results show that Apo E may be associated with sites of beta amyloid fibril formation in diffuse plaques in AD brain, but they also suggest that factors other than Apo E, probably local, may influence fibrillogenesis

Amyloidosis is a generic term for a group of clinically and biochemically diverse diseases that are characterized by the deposition of an insoluble fibrillar protein in the extracellular space. Over 16 biochemically distinct amyloids are known. Despite this diversity, all amyloids have a particular ultrastructural and tinctorial appearance, a beta-pleated sheet structure, and are codeposited with a group of amyloid-associated proteins. The most common amyloidosis is Alzheimer's disease (AD), where A beta is the main component of the amyloid. Recently it has been found that A beta exists as a normal soluble protein (sA beta) in biological fluids. This links AD more closely to some of the systemic amyloidoses, where the amyloid precursor is found in the circulation normally. Numerous mutations have been found in the A beta precursor (beta PP) gene, associated with familial AD. Many mutations are also found in some of the hereditary systemic amyloidoses. For example, over 40 mutations in the transthyretin (TTR) gene are associated with amyloid. However, both A beta and TTR related amyloid deposition can occur with no mutation. The pathogenesis of amyloid is complex, and appears to be associated with genetic and environmental risk factors that can be similar in the systemic and cerebral amyloidoses