Beta-amyloid production, aggregation, and clearance as targets for therapy in Alzheimer's disease

Formation of amyloid aggregates from human lysozyme and its disease‐associated variants using hydrostatic pressure

Formation of amyloid deposits from the Ile56Thr or Asp67His variants of human lysozyme is a hallmark of autosomal hereditary systemic amyloidosis. It has recently been shown that amyloid fibrils can be formed in vitro from wild-type (WT), I56T, or D67H lysozyme variants upon prolonged incubation at acidic pH and elevated temperatures (1). Here, we have used hydrostatic pressure as a tool to generate amyloidogenic states of WT and variant lysozymes at physiological pH. WT or variant lysozyme samples were initially compressed to 3.5 kbar (at 57 degrees C, pH 7.4). Decompression led to the formation of amyloid fibrils, protofibrils, or globular aggregates, as indicated by light scattering, thioflavin T fluorescence, and transmission electron microscopy analysis. Increased 1-anilinonaphthalene-8-sulfonate binding to the proteins was also observed, indicating exposure of hydrophobic surface area. Thus, pressure appears to induce a conformational state of lysozyme that aggregates readily upon decompression. These results support the notion that amyloid aggregation results from the formation of partially unfolded protein conformations and suggest that pressure may be a useful tool for the generation of the amyloidogenic conformations of lysozyme and other proteins.

Novel Chelators for Central Nervous System Disorders That Involve Alterations in the Metabolism of Iron and Other Metal Ions

Recent evidence suggests that iron (Fe) and other metals play a role in a number of neurodegenerative diseases including Friedreich's ataxia, Alzheimer's disease, Huntington's disease, and Parkinson's disease. In this review, the role of Fe and other metals in the pathology of these conditions is assessed and the potential of Fe chelators for treatment is discussed. Lipophilic chelators have been designed that may be capable of crossing the blood-brain barrier, a property lacking in desferrioxamine (DFO), a chelator in widespread clinical use. A far less commonly used chelator, clioquinol, has already shown activity in vivo in animal models and also in Alzheimer's disease patients. Considering that there is no effective treatment for many neurological diseases, the therapeutic use of lipophilic Fe chelators remains a potential strategy that requires investigation. In particular, we discuss the development of several series of aroylhydrazone chelators that could have high potential in the treatment of these diseases.

Simultaneous changes in secretory amyloid precursor protein and β-amyloid peptide release from rat hippocampus by activation of muscarinic receptors

Amyloid deposits in Alzheimer's disease (AD) are composed of beta-amyloid peptides (Abeta) that are derived from the larger amyloid precursor protein (APP). A number of studies with various transfected cell lines demonstrated that either APP secretion or Abeta production could be modulated by specific muscarinic receptor activation. In the present study, we investigated the simultaneous changes of neurotrophic secretory APP (APPs) and neurotoxic Abeta release from rat hippocampus by activation of muscarinic receptors. The treatment with carbachol (10 microM-1 mM) resulted in the increased APPs release and simultaneously reduced Abeta production from the hippocampus slices in a concentration-dependent manner. The carbachol-stimulated APPs release was blocked by the nonselective M antagonist atropine and the M(1) antagonist pirenzepine, but was not significantly affected by the M(2) antagonist methoctramine, demonstrating that APP processing was regulated mainly via M(1) receptor in the rat hippocampus. The effect of carbachol-stimulated APPs secretion was further verified in CHOm(1) cells stably expressing human muscarinic M(1) receptors. These data suggest that selective M(1) receptor agonists might execute a dual action of increasing APPs release and decreasing Abeta formation to modify the AD process.

Folding and stability of the extracellular domain of the human amyloid precursor protein

The beta-amyloid peptide (A beta), the major component of the senile plaques found in the brains of Alzheimer's disease patients, is derived from proteolytic processing of a transmembrane glycoprotein known as the amyloid precursor protein (APP). Human APP exists in various isoforms, of which the major ones contain 695, 751, and 770 amino acids. Proteolytic cleavage of APP by alpha- or beta-secretases releases the extracellular soluble fragments sAPP alpha or sAPP beta, respectively. Despite the fact that sAPP alpha plays important roles in both physiological and pathological processes in the brain, very little is known about its structure and stability. We have recently presented a structural model of sAPP alpha 695 obtained from small-angle x-ray scattering measurements (Gralle, M., Botelho, M. M., Oliveira, C. L. P., Torriani, I., and Ferreira, S. T. (2002) Biophys. J. 83, 3513-3524). We now report studies on the folding and stabilities of sAPP alpha 695 and sAPP alpha 770. The combined use of intrinsic fluorescence, 4-4'-Dianilino-1,1'binaphthyl-5,5'-disulfonic acid (bis-ANS) fluorescence, circular dichroism, differential ultraviolet absorption, and small-angle x-ray scattering measurements of the equilibrium unfolding of sAPP alpha 695 and sAPP alpha 770 by GdnHCl and urea revealed multistep folding pathways for both sAPP alpha isoforms. Such stepwise folding processes may be related to the identification of distinct structural domains in the three-dimensional model of sAPP alpha. Furthermore, the relatively low stability of the native state of sAPP alpha suggests that conformational plasticity may play a role in allowing APP to interact with a number of distinct physiological ligands.

Design strategies for anti-amyloid agents

Numerous diseases have been linked to a common pathogenic process called amyloidosis, whereby proteins or peptides clump together in the brain or body to form toxic soluble oligomers and/or insoluble fibres. An attractive strategy to develop therapies for these diseases is therefore to inhibit or reverse protein/peptide aggregation. A diverse range of small organic ligands have been found to act as aggregation inhibitors. Alternatively, the wild-type peptide can be derivatised so that it still binds to the amyloid target, but prevents further aggregation. This can be achieved by adding a bulky group or charged amino acid to either end of the peptide, or by incorporating proline residues or N-methylated amide groups.

Cellular FLICE-inhibitory protein: an attractive therapeutic target?

Cellular FLIP (c-FLIP), also known as FLICE-inhibitory protein, has been identified as an inhibitor of apoptosis triggered by engagement of death receptors (DRs) such as Fas or TRAIL (TNF-related apoptosis-inducing ligand). cFLIP is recruited to DR signalling complexes, where it prevents caspase activation. Animal models have indicated that c-FLIP plays an important role in T cell proliferation and heart development. Abnormal c-FLIP expression has been identified in various diseases such as multiple sclerosis (MS), Alzheimer's disease (AD), diabetes mellitus, rheumatoid arthritis (RA) and various cancers. This review focuses on recent insights into c-FLIP dysregulation associated with human diseases and addresses the possibilities of using c-FLIP as a therapeutic target.