Cytoplasmic SET induces tau hyperphosphorylation through a decrease of methylated phosphatase 2A.

BACKGROUND: The neuronal cytoplasmic localization of SET, an inhibitor of the phosphatase 2A (PP2A), results in tau hyperphosphorylation in the brains of Alzheimer patients through mechanisms that are still not well defined. RESULTS: We used primary neurons and mouse brain slices to show that SET is translocated to the cytoplasm in a manner independent of both its cleavage and over-expression. The localization of SET in the cytoplasm, either by the translocation of endogenous SET or by internalization of the recombinant full-length SET protein, induced tau hyperphosphorylation. Cytoplasmic recombinant full-length SET in mouse brain slices induced a decrease of PP2A activity through a decrease of methylated PP2A levels. The levels of methylated PP2A were negatively correlated with tau hyperphosphorylation at Ser-202 but not with the abnormal phosphorylation of tau at Ser-422. CONCLUSIONS: The presence of full-length SET in the neuronal cytoplasm is sufficient to impair PP2A methylation and activity, leading to tau hyperphosphorylation. In addition, our data suggest that tau hyperphosphorylation is regulated by different mechanisms at distinct sites. The translocation of SET to the neuronal cytoplasm, the low activity of PP2A, and tau hyperphosphorylation are associated in the brains of Alzheimer patients. Our data show a link between the translocation of SET in the cytoplasm and the decrease of methylated PP2A levels leading to a decrease of PP2A activity and tau hyperphosphorylation. This chain of events may contribute to the pathogenesis of Alzheimer disease.

Role of cholesterol metabolism in the pathogenesis of Alzheimer's disease.

PURPOSE OF REVIEW: Cholesterol has been shown to stimulate the cleavage of amyloid precursor protein (APP) into amyloid peptides involved in Alzheimer's disease. However, high level of peripheral cholesterol as a risk factor for Alzheimer's disease is still debated. This current review provides an update of the recent literature on cholesterol and APP metabolisms in the brain. RECENT FINDINGS: First, a new relationship between neuronal APP and cholesterol has been shown in which this protein controls cholesterol turnover required for neuronal activity. Second, oxysterols are able to stimulate the synthesis of ATP-binding cassette transporters involved in the exchange of amyloid peptides between the blood and the brain. Third, changes in APP targeting to lipid rafts and/or their composition in cholesterol regulate amyloid peptide production. SUMMARY: These recent findings open new areas of investigations to control the neuronal activity and to decrease the amyloid peptide levels in brain, opening on new preventive and therapeutic strategies for Alzheimer's disease.

Citrulline diet supplementation improves specific age-related raft changes in wild-type rodent hippocampus.

The levels of molecules crucial for signal transduction processing change in the brain with aging. Lipid rafts are membrane microdomains involved in cell signaling. We describe here substantial biophysical and biochemical changes occurring within the rafts in hippocampus neurons from aging wild-type rats and mice. Using continuous sucrose density gradients, we observed light-, medium-, and heavy raft subpopulations in young adult rodent hippocampus neurons containing very low levels of amyloid precursor protein (APP) and almost no caveolin-1 (CAV-1). By contrast, old rodents had a homogeneous age-specific high-density caveolar raft subpopulation containing significantly more cholesterol (CHOL), CAV-1, and APP. C99-APP-Cter fragment detection demonstrates that the first step of amyloidogenic APP processing takes place in this caveolar structure during physiological aging of the rat brain. In this age-specific caveolar raft subpopulation, levels of the C99-APP-Cter fragment are exponentially correlated with those of APP, suggesting that high APP concentrations may be associated with a risk of large increases in beta-amyloid peptide levels. Citrulline (an intermediate amino acid of the urea cycle) supplementation in the diet of aged rats for 3 months reduced these age-related hippocampus raft changes, resulting in raft patterns tightly close to those in young animals: CHOL, CAV-1, and APP concentrations were significantly lower and the C99-APP-Cter fragment was less abundant in the heavy raft subpopulation than in controls. Thus, we report substantial changes in raft structures during the aging of rodent hippocampus and describe new and promising areas of investigation concerning the possible protective effect of citrulline on brain function during aging.

PAT1 induces cell death signal and SET mislocalization into the cytoplasm by increasing APP/APLP2 at the cell surface.

The cleavage of amyloid precursor protein (APP) by caspases unmasks a domain extending from membrane to caspase cleavage site. This domain induces apoptosis in vitro and in vivo when overexpressed in neurons through the help of an internalization vector. In this model, we previously showed that SET rapidly binds to the internalized domain and is involved in downstream deleterious effects. Under these conditions SET mislocalizes from the nucleus to the cytoplasm, as in Alzheimer's disease (AD). In this report using the same model, we show that PAT1 attaches to the internalized domain earlier than SET and that this binding causes an increase in the levels of APP and APLP2 at the cell surface. Down regulation experiments of PAT1 and of APP and APLP2 show that the increase of the levels of APP and APLP2 at the cell surface triggers the cell death signal and SET mislocalization into the cytoplasm. In the context of AD these data suggest that mislocalization of SET into the cytoplasm may occur downstream of first cell death signal events involving PAT1 protein.

Clearance of amyloid-beta peptide by neuronal and non-neuronal cells: proteolytic degradation by secreted and membrane associated proteases.

Deposition of amyloid-beta peptide (Abeta) in the brain is an early and invariant feature of all forms of Alzheimer's disease (AD). As for all proteins or peptides, the steady-state level of Abeta peptide is determined not only by its production, but also by its degradation. So, overactive proteases involved in generating Abeta from amyloid precursor protein or underactive Abeta-degrading enzymes could lead to abnormal Abeta deposition in the brain. Since in the sporadic forms of AD (90% of all AD cases) an impaired clearance of Abeta appears to be at the origin of its aggregation and tissue deposition, we have investigated its proteolytic degradation by several neuronal and non-neuronal cells. In this report, we show that these cell types exhibit a similar profile of Abeta-degradation by cell-surface and secreted proteases which were respectively characterized as metallo- and serine proteases. By using a combination of the liquid chromatography/on-line mass spectrometry, we demonstrate that: (i)-the membrane associated protease(s) hydrolizes Abeta40 essentially at Lys(28) Gly(29), Phe(19) Phe(20) and Val(18) Phe(19) bonds; and (ii)-the secreted protease(s) cleaves the generating fragments Abeta (1-28), Abeta (1-19), Abeta (1-18) at His(14) Gln(15) bond and also Abeta (1-28) at Phe(20) Ala(21) and Asp(23) Val(24) sites. This is the first time our results define a proteolytic degradation process of Abeta40 that appears to be independent of the cell type and may represent a general pattern of its enzymatic clearance.

Endogenous C-terminal fragments of beta-amyloid precursor protein from Xenopus laevis skin exudate.

Using a monoclonal antibody against the entire C-terminal end of human APP(695) (643-695 sequence) and a monoclonal antibody directed against human beta[1-40] amyloid peptide (betaA), we show the existence of endogenous peptides proteolytically derived from APP in skin exudate of the non transgenic Xenopus laevis frog. The majority of the immunoreactivity is found associated with a 30 kDa molecular species. Biochemical fractionation followed by mass spectrometry identification allowed us to assign this molecular species to C-terminal APP fragments containing all or part of betaA. According to the nature of N- and C-terminal amino acids we identified endogenous beta-, gamma-, epsilon-secretase-like activities, caspase-like activity and numerous endogenous cleavage sites within the beta-amyloid sequence at same sites as those observed in human betaA sequence. All these homologies with human indicate that X. laevis skin exudate is a good natural model to study betaA metabolism. In this way, interestingly, we identified endogenous cleavages at prohormone convertase-like sites not yet described at the same sites in human. Finally, all identified peptide fragments were stably associated with a 20.2 kDa protein. These new observed features suggest new research pathways concerning human betaA metabolism and carriage of hydrophobic peptide fragments issued from APP processing.

Specific cleavage of beta-amyloid peptides by a metallopeptidase from Xenopus laevis skin secretions.

Dactylysin (EC 3.5.24.60) is a metalloendopeptidase first isolated from the skin granular gland secretions of Xenopus laevis. This peptidase hydrolyzes bonds on the amino-terminus of singlets and between doublets of hydrophobic amino acids and was considered to play a role in the in vivo inactivation of biologically active regulatory peptides. Here, we show that dactylysin has also the ability to cleave human beta[1-40]-amyloid peptide and related peptides. Cleavage of the wild type beta[1-40]-amyloid peptide form, and to a lesser extent Flemish and Dutch mutants, occurred predominantly at the His14-Glu15 bond. We demonstrate that frog skin exudate contains a full-length amyloid protein precursor detected by immunochemical cross-reactivity with monoclonal antibody against C-terminal human amyloid protein precursor. The possibility that dactylysin, might be involved in normal catabolism of beta amyloid peptide of Xenopus laevis is discussed.