Point mutations in the presenilin-1 gene (PS1) are a major cause of familial Alzheimer's disease. They result in a selective increase in the production of the amyloidogenic peptide amyloid-beta(1-42) by proteolytic processing of the amyloid precursor protein (APP). Here we investigate whether PS1 is also involved in normal APP processing in neuronal cultures derived from PS1-deficient mouse embryos. Cleavage by alpha- and beta-secretase of the extracellular domain of APP was not affected by the absence of PS1, whereas cleavage by gamma-secretase of the transmembrane domain of APP was prevented, causing carboxyl-terminal fragments of APP to accumulate and a fivefold drop in the production of amyloid peptide. Pulse-chase experiments indicated that PS1 deficiency specifically decreased the turnover of the membrane-associated fragments of APP. As in the regulation of cholesterol metabolism by proteolysis of a membrane-bound transcription factor, PS1 appears to facilitate a proteolytic activity that cleaves the integral membrane domain of APP. Our results indicate that mutations in PS1 that manifest clinically cause a gain of function and that inhibition of PS1 activity is a potential target for anti-amyloidogenic therapy in Alzheimer's disease.
(2) and London mutation(s) (3) alter APP processing, causing increased production of the A peptide of 42 amino acids (4), hypothesized to be pivotal in AD pathology (1, 5). Early onset familial AD caused by mutations in the presenilin genes supports this hypothesis, because they increase production of A (42) peptide (6, 7) due to the gain of an unknown function (8). The extensive cell biological definition of the metabolic effects of the different mutations in APP in vitro requires matching analysis of their physiological impact in vivo. Transgenic mice with wild type and different mutant forms of APP have been generated and the original, most wanted end point, i.e. AD-like amyloid plaques in mouse brain, was obtained (9, 10), accompanied by cognitive deficits (11) and by hyperphosphorylation of protein tau (12). In other transgenic mouse strains overexpression of APP caused behavioral, synaptotrophic, and neurodegenerative effects, accelerated senescence, and premature death, in the absence of amyloid deposits (13-16). Intracellular expression of the A peptide yielded mice with extensive neuronal loss but no amyloidosis (17). Overexpression of the C-terminal domain of APP caused neuronal degeneration (18), whereas in another model, pre-amyloid deposits, hippocampal cell loss, and cognitive deficits were documented (19).We have generated additional transgenic mouse strains, expressing human APP, either wild type or the London or Swedish clinical mutations, from the neuron-specific mouse thy-1 gene promoter. Their phenotype was analyzed by biochemical, histochemical, behavioral, electrophysiological, and pharmacological methods. Measurements of different APP metabolites in brain demonstrated that increased A(42) levels correlated with the formation of amyloid plaques in the brain of old APP/London transgenic mice. The plaques were extensively characterized immunohistochemically and displayed many aspects typically observed in the brain of AD patients. As opposed to plaques that developed only after at least 12 months of age, other deficits were observed from 3 months onwards and included cognitive impairment, decreased long term potentiation, differential glutamatergic responses, aggression, and neophobia, among others. These signs were largely independent of the actual isoform or mutant of APP that was expressed, were not correlated with a single APP metabolite, and are dissociated in time from plaque formation. These mice will be good models to study both early and late, neuropathological, and clinical aspects related to Alzheimer's disease. EXPERIMENTAL PROCEDURESGeneration of Transgenic Mice-cDNA coding for human wild type APP (695 isoform), the Swedish (K670N,M671L) mutant (770 isoform), and the London (V642I) mutant (695 isoform) were cloned in the pTSC vector in the mouse thy-1 gene (16). The purified, linearized minigenes were microinjected into prenuclear embryos from superovulated FVB/N females.Antibodies-Rabbit antisera B11/4 and B12/4, generated against a *
Mutations in the homologous presenilin 1 (PS1) and presenilin 2 (PS2) genes cause the most common and aggressive form of familial Alzheimer's disease. Although PS1 function and dysfunction have been extensively studied, little is known about the function of PS2 in vivo. To delineate the relationships of PS2 and PS1 activities and whether PS2 mutations involve gain or loss of function, we generated PS2 homozygous deficient (؊͞؊) and PS1͞PS2 double homozygous deficient mice. In contrast to PS1 ؊͞؊ mice, PS2 ؊͞؊ mice are viable and fertile and develop only mild pulmonary fibrosis and hemorrhage with age. Absence of PS2 does not detectably alter processing of amyloid precursor protein and has little or no effect on physiologically important apoptotic processes, indicating that Alzheimer's disease-causing mutations in PS2, as in PS1, result in gain of function. Although PS1 ؉͞؊ PS2 ؊͞؊ mice survive in relatively good health, complete deletion of both PS2 and PS1 genes causes a phenotype closely resembling full Notch-1 deficiency. These results demonstrate in vivo that PS1 and PS2 have partially overlapping functions and that PS1 is essential and PS2 is redundant for normal Notch signaling during mammalian embryological development.
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