Ischemic rats as a model in the study of the neurobiological role of human beta-amyloid peptide. Time-dependent disappearing diffuse amyloid plaques in brain.

Brains from patients with Alzheimer's disease contain diffuse and senile amyloid plaques. Using an experimental model, we have addressed the issue whether diffuse plaques of amyloid persist, develop with time, or both, in rats injected with human beta-amyloid-(1-42)-peptide for 3 and 12 mon after brain ischemia. Rats receiving beta-amyloid peptide for 3 months after brain ischemia demonstrated widespread diffuse amyloid plaques in hippocampus and cerebral cortex. Neuronal, glial, ependymal, endothelial and pericyte cell bodies were observed filled with beta-amyloid peptide. No staining was observed in control brains. In the group alive 1 year no deposition of human beta-amyloid peptide was observed, too. Direct evidence that diffuse amyloid plaques can disappear in the brain is thus provided for the first time.

Possible reverse transport of beta-amyloid peptide across the blood-brain barrier.

Our experiments were performed to test the hypothesis that human beta-amyloid peptide 42 (beta A) is able to enter and exit the brain parenchyma through the blood-brain barrier. In an effort to determine the effect of beta A in an animal model, we have injected beta A i.v. into rats following single and repeated brain ischemia. Rats were sacrificed at 3 and 12 months after injection and beta A was localized by monoclonal antibody (mAb) 4G8. The present observations revealed an abundant presence of beta A in the extracellular space of the brain, which appeared to be dilated, and a vigorous uptake of beta A into the cytoplasm of endothelial and ependymal cells, pericytes, astrocytes and neurons. Some of the beta A deposits were associated and/or had migrated to the vessels and to the ventricles, and by 3 months a significant amount of beta A was directly associated with the vessels and was observed inside the ventricular space. Virtually no soluble and aggregating beta A was found in brain tissue 1 year later. This suggests that phagocytic pericytes and astrocytes take up exogenous beta A in an attempt to clear the peptide from the brain extracellular space and deliver it to the circulation. Further, direct removal of beta A from the ventricles by the bloodstream is also possible. These observations suggest that a reverse transport of beta A across endothelial cells of microvessels represents one of the possible mechanisms responsible for removal of extravasated beta A. The findings of the present study indicate that in normal conditions beta A is rapidly cleared from the cerebrospinal fluid and brain parenchyma, suggesting that irreversible changes in the physico-chemical properties of the cerebrovascular endothelial cell surface are involved in beta A deposition in the brain in Alzheimer's disease (AD).