Distinct in vivo roles of secreted APP ectodomain variants APPsα and APPsβ in regulation of spine density,synaptic plasticity,and cognition

Increasing evidence suggests that synaptic functions of the amyloid precursor protein (APP), which is key to Alzheimer pathogenesis, may be carried out by its secreted ectodomain (APPs). The specific roles of APPsα and APPsβ fragments, generated by non‐amyloidogenic or amyloidogenic APP processing, respectively, remain however unclear. Here, we expressed APPsα or APPsβ in the adult brain of conditional double knockout mice (cDKO) lacking APP and the related APLP2. APPsα efficiently rescued deficits in spine density, synaptic plasticity (LTP and PPF), and spatial reference memory of cDKO mice. In contrast, APPsβ failed to show any detectable effects on synaptic plasticity and spine density. The C‐terminal 16 amino acids of APPsα (lacking in APPsβ) proved sufficient to facilitate LTP in a mechanism that depends on functional nicotinic α7‐nAChRs. Further, APPsα showed high‐affinity, allosteric potentiation of heterologously expressed α7‐nAChRs in oocytes. Collectively, we identified α7‐nAChRs as a crucial physiological receptor specific for APPsα and show distinct in vivo roles for APPsα versus APPsβ. This implies that reduced levels of APPsα that might occur during Alzheimer pathogenesis cannot be compensated by APPsβ.     

Anti-amyloid precursor protein immunoglobulins inhibit amyloid-β production by steric hindrance

The cleavage of amyloid precursor protein (APP) by β- and γ-secretases results in the production of amyloid-β (Aβ) in Alzheimer's disease. We raised two monoclonal antibodies, 2B3 and 2B12, that recognize the β-secretase cleavage site on APP but not Aβ. We hypothesized that these antibodies would reduce Aβ levels via steric hindrance of β-secretase. Both antibodies decreased extracellular Aβ levels from astrocytoma cells, but 2B3 was more potent than 2B12. Levels of soluble sAPPα from the nonamyloidogenic α-secretase pathway and intracellular APP were not affected by either antibody nor were there any effects on cell viability. 2B3 exhibited a higher affinity for APP than 2B12 and its epitope appeared to span the cleavage site, whereas 2B12 bound slightly upstream. Both of these factors probably contribute to its greater effect on Aβ levels. After 60 min incubation at pH 4.0, most 2B3 and 2B12 remained bound to their antigen, suggesting that the antibodies will remain bound to APP in the acidic endosomes where β-secretase cleavage probably occurs. Only 2B3 and 2B12, but not control antibodies, inhibited the cleavage of sAPPα by β-secretase in a cell-free assay where the effects of antibody internalization and intracellular degradation were excluded. 2B3 virtually abolished this cleavage. In addition, levels of C-terminal APP fragments, generated following β-secretase cleavage (βCTF), were significantly reduced in cells after incubation with 2B3. These results strongly suggest that anti-cleavage site IgGs can generically reduce Aβ levels via inhibition of β-secretase by steric hindrance and may provide a novel alternative therapy for Alzheimer's disease.     

Multiple γ-secretase product peptides are coordinately increased in concentration in the cerebrospinal fluid of a subpopulation of sporadic Alzheimer's disease subjects

ABSTRACT: BACKGROUND: Alcadeinα (Alcα) is a neuronal membrane protein that colocalizes with the Alzheimer's amyloid-β precursor protein (APP). Successive cleavage of APP by β- and γ-secretases generates the aggregatable amyloid-β peptide (Aβ), while cleavage of APP or Alcα by α- and γ-secretases generates non-aggregatable p3 or p3-Alcα peptides. Aβ and p3-Alcα can be recovered from human cerebrospinal fluid (CSF). We have previously reported alternative processing of APP and Alcα in the CSF of some patients with sporadic mild cognitive impairment (MCI) and AD (SAD). RESULTS: Using the sandwich enzyme-linked immunosorbent assay (ELISA) system that detects total p3-Alcα, we determined levels of total p3-Alcα in CSF from subjects in one of four diagnostic categories (elderly controls, MCI, SAD, or other neurological disease) derived from three independent cohorts. Levels of Aβ40 correlated with levels of total p3-Alcα in all cohorts. CONCLUSIONS: We confirm that Aβ40 is the most abundant Aβ species, and we propose a model in which CSF p3-Alcα can serve as a either (1) a nonaggregatable surrogate marker for γ-secretase activity; (2) as a marker for clearance of transmembrane domain peptides derived from integral protein catabolism; or (3) both. We propose the specification of an MCI/SAD endophenotype characterized by co-elevation of levels of both CSF p3-Alcα and Aβ40, and we propose that subjects in this category might be especially responsive to therapeutics aimed at modulation of γ-secretase function and/or transmembrane domain peptide clearance. These peptides may also be used to monitor the efficacy of therapeutics that target these steps in Aβ metabolism.     

O-GlcNAcylation increases non-amyloidogenic processing of the amyloid-β precursor protein (APP)

The amyloid-β precursor protein (APP) was shown to be O-GlcNAcylated 15 years ago, but the effect of this modification on APP processing and formation of the Alzheimer’s disease associated amyloid-β (Aβ) peptide has so far not been investigated. Here, we demonstrate with pharmacological tools or siRNA that O-GlcNAcase and O-GlcNAc transferase regulate the level of O-GlcNAcylated APP. We also show that O-GlcNAcylation increases non-amyloidogenic α-secretase processing, resulting in increased levels of the neuroprotective sAPPα fragment and decreased Aβ secretion. Our results implicate O-GlcNAcylation as a potential therapeutic target for Alzheimer’s disease.     

The Swedish APP mutation alters the effect of genetically reduced BACE1 expression on the APP processing

Inhibition of β-secretase (BACE1) is a key therapeutic approach in Alzheimer's disease (AD), as BACE1 initiates amyloid-β (Aβ) cleavage from the β-amyloid precursor protein (APP). As Aβ reductions in mice lacking one BACE1 allele diverged considerably between studies we investigated the effect of BACE1 knock-out in more detail. With both BACE1 alleles the Swedish mutation (APP23 mice) increased APP processing and shifted it towards the β-secretase pathway as compared with non-mutated APP expressed at a similar level (APP51/16 mice). This effect was much smaller then observed in cell culture. An about 50% decrease in BACE1 enzyme activity resulted in a sub-proportional Aβ reduction with the Swedish mutation (-20%) and even less for non-mutated APP (-16%). In wild-type mice, the Aβ reduction may be even further diminished. Other metabolites of the β-secretase pathway decreased accordingly while the alternative α-secretase pathway increased. Complete BACE1 deletion strongly enhanced these changes. The remaining Aβ signal also described by others can be explained by assay cross-reactivity with other APP metabolites supporting BACE1 as the major β-secretase. Our data indicate that BACE1 is in excess over APP at the cleavage site(s). Alterations in APP expression or substrate properties, therefore, quantitatively change its cleavage and Aβ generation.     

Increased secreted amyloid precursor protein-α (sAPPα) in severe autism: proposal of a specific, anabolic pathway and putative biomarker

Autism is a neurodevelopmental disorder characterized by deficits in verbal communication, social interactions, and the presence of repetitive, stereotyped and compulsive behaviors. Excessive early brain growth is found commonly in some patients and may contribute to disease phenotype. Reports of increased levels of brain-derived neurotrophic factor (BDNF) and other neurotrophic-like factors in autistic neonates suggest that enhanced anabolic activity in CNS mediates this overgrowth effect. We have shown previously that in a subset of patients with severe autism and aggression, plasma levels of the secreted amyloid-β (Aβ) precursor protein-alpha form (sAPPα) were significantly elevated relative to controls and patients with mild-to-moderate autism. Here we further tested the hypothesis that levels of sAPPα and sAPPβ (proteolytic cleavage products of APP by α- and β-secretase, respectively) are deranged in autism and may contribute to an anabolic environment leading to brain overgrowth. We measured plasma levels of sAPPα, sAPPβ, Aβ peptides and BDNF by corresponding ELISA in a well characterized set of subjects. We included for analysis 18 control, 6 mild-to-moderate, and 15 severely autistic patient plasma samples. We have observed that sAPPα levels are increased and BDNF levels decreased in the plasma of patients with severe autism as compared to controls. Further, we show that Aβ1-40, Aβ1-42, and sAPPβ levels are significantly decreased in the plasma of patients with severe autism. These findings do not extend to patients with mild-to-moderate autism, providing a biochemical correlate of phenotypic severity. Taken together, this study provides evidence that sAPPα levels are generally elevated in severe autism and suggests that these patients may have aberrant non-amyloidogenic processing of APP.     

Autoreactive-Aβ antibodies promote APP β-secretase processing

Several prior investigations of Alzheimer's disease (AD) patients have indicated naturally occurring autoantibodies against amyloid-β (Aβ) species are produced. Although many studies have focused on the relative concentrations or binding affinities of autoantibodies against Aβ-related proteins in AD and aging, data regarding their functional properties are limited. It is generally believed that these antibodies act to aid in clearance of Aβ. However, as antibodies which bind to Aβ also typically bind to the parent amyloid precursor protein (APP), we reasoned that certain Aβ-targeting autoantibodies may bind to APP thereby altering its conformation and processing. Here we show for the first time, that naturally occurring Aβ-reactive autoantibodies isolated from AD patients, but not from healthy controls, promote β-secretase activity in cultured cells. Furthermore, using monoclonal antibodies to various regions of Aβ, we found that antibodies generated against the N-terminal region, especially Aβ(1-17) , dose dependently promoted amyloidogenic processing of APP viaβ-secretase activation. Thus, this property of certain autoantibodies in driving Aβ generation could be of etiological importance in the development of sporadic forms of AD. Furthermore, future passive or active anti-Aβ immunotherapies must consider potential off-target effects resulting from antibodies targeting the N-terminus of Aβ, as co-binding to the corresponding region of APP may actually enhance Aβ generation.     

The senescence accelerated mouse (SAMP8) as a model for oxidative stress and Alzheimer's disease

The senescence accelerated mouse (SAMP8) is a spontaneous animal model of overproduction of amyloid precursor protein (APP) and oxidative damage. It develops early memory disturbances and changes in the blood-brain barrier resulting in decreased efflux of amyloid-β protein from the brain. It has a marked increase in oxidative stress in the brain. Pharmacological treatments that reduce oxidative stress improve memory. Treatments that reduce amyloid-β (antisense to APP and antibodies to amyloid-β) not only improve memory but reduce oxidative stress. Early changes in lipid peroxidative damage favor mitochondrial dysfunction as being a trigger for amyloid-β overproduction in this genetically susceptible mouse strain. This sets in motion a cycle where the increased amyloid-beta further damages mitochondria. We suggest that this should be termed the Inflammatory-Amyloid Cycle and may well be similar to the mechanisms responsible for the pathophysiology of Alzheimer's disease. This article is part of a Special Issue entitled: Antioxidants and Antioxidant Treatment in Disease.     

N-cadherin enhances APP dimerization at the extracellular domain and modulates Aβ production

Sequential processing of amyloid precursor protein (APP) by β- and γ-secretase leads to the generation of amyloid-β (Aβ) peptides, which plays a central role in Alzheimer's disease pathogenesis. APP is capable of forming a homodimer through its extracellular domain as well as transmembrane GXXXG motifs. A number of reports have shown that dimerization of APP modulates Aβ production. On the other hand, we have previously reported that N-cadherin-based synaptic contact is tightly linked to Aβ production. In the present report, we investigated the effect of N-cadherin expression on APP dimerization and metabolism. Here, we demonstrate that N-cadherin expression facilitates cis-dimerization of APP. Moreover, N-cadherin expression led to increased production of Aβ as well as soluble APPβ, indicating that β-secretase-mediated cleavage of APP is enhanced. Interestingly, N-cadherin expression affected neither dimerization of C99 nor Aβ production from C99, suggesting that the effect of N-cadherin on APP metabolism is mediated through APP extracellular domain. We confirmed that N-cadherin enhances APP dimerization by a novel luciferase-complementation assay, which could be a platform for drug screening on a high-throughput basis. Taken together, our results suggest that modulation of APP dimerization state could be one of mechanisms, which links synaptic contact and Aβ production.     

Defective neurite extension is caused by a mutation in amyloid β/A4 (Aβ) protein precursor found in Familial Alzheimer's Disease

Clonal central nervous system neuronal cells, B103, do not synthesize detectable endogenous APP or APLP. B103 cells transfected with both wild-type (B103/APP) and mutant APP construct (B103/APPΔNL) secreted comparable amounts of soluble forms of APP (sAPP). B103/APP cells produced sAPP and cleaved at amyloid β/A4 (Aβ) 16, the α-secretase site, and B103/APPΔNL cells produced sAPPβ cleaved at Aβ 1, the β-secretase site. B103/APPΔNL cells developed fewer neurites than B103/APP cells in a serum-free defined medium. Neurite numbers of parent B103 cells were increased by the 50% conditioned medium (CM) from B103/APP cells but reduced by the CM from B103/APPΔNL cells. Chemically synthesized Aβ at concentration levels higher than 1 nM reduced numbers of neurites from B103 or B103/APPΔNL cells. However, Aβ at 1–100 nM could not reduce the neurite number of B103/APP cells. The protective activity against Aβ's deleterious effect to reduce neurite numbers was attributed to sAPPα in the CM. Although sAPPα could block the effect of Aβ, sAPPβ could not do so under the identical condition, suggesting the importance of the C-terminal 15-amino acid sequence in sAPPα. Nevertheless, sAPPα's protective activity required the N-terminal sequence around RERMS, previously identified to be the active domain of sAPPβ. The overall effect of APP mutation which overproduced Aβ and sAPPβ and underproduced sAPPα was a marked decline in the neurotrophic effect of APP. We suggest that the disruption of balance between the detrimental effect of Aβ and the trophic effect of sAPP may be important in the pathogenesis of AD caused by this pathogenic APP mutation © 1997 John Wiley & Sons, Inc. J Neurobiol 32: 469–480, 1997     

Metallothionein-III increases ADAM10 activity in association with furin,PC7, and PKCα during non-amyloidogenic processing

A-disintegrin and metalloproteinase 10 (ADAM10) is involved in the generation of amyloid-β (Aβ) during amyloid precursor protein (APP) processing, and has a protective effect against Aβ neurotoxicity. We explored how metallothionein-III (MT-III) is regulated in the non-amyloidogenic pathway to generate soluble APPα (sAPPα). MT-??? increased sAPPα levels and reduced Aβ peptide levels, but did not affect ADAM10 expression. However, MT-III increased the activity of ADAM10. MT-???-induced sAPPα secretion, and Aβ peptide formation was blocked by specific inhibitors of furin, proprotein convertase7 (PC7), and PKCα. These results demonstrate that MT-??? increases the amount of active ADAM10 in association with furin, PC7 and PKCα.     

Genetic and pharmacological evidence of intraneuronal Aβ accumulation in APP transgenic mice

Intraneuronal punctate immunostaining in Alzheimer’s disease brain and amyloid-β precursor protein (APP) transgenic mice has been suggested to represent Aβ, but this is somewhat controversial. Here we show that both biochemical Aβ levels and intraneuronal immunostaining are reduced in APP transgenic mice when γ-secretase is inhibited. Moreover, BACE-1 deficient APP transgenic mice show neither Aβ production nor intraneuronal immunostaining. Our findings suggest that the punctate immunostaining with APP antibodies is due to Aβ that has accumulated inside neurons. Similar type of intraneuronal Aβ accumulation, which precedes senile plaque formation, may link Aβ to tauopathy and neurodegeneration in Alzheimer’s disease pathogenesis.     

GULP1 is a novel APP-interacting protein that alters APP processing

Altered production of Aβ (amyloid-β peptide), derived from the proteolytic cleavage of APP (amyloid precursor protein), is believed to be central to the pathogenesis of AD (Alzheimer's disease). Accumulating evidence reveals that APPc (APP C-terminal domain)-interacting proteins can influence APP processing. There is also evidence to suggest that APPc-interacting proteins work co-operatively and competitively to maintain normal APP functions and processing. Hence, identification of the full complement of APPc-interacting proteins is an important step for improving our understanding of APP processing. Using the yeast two-hybrid system, in the present study we identified GULP1 (engulfment adaptor protein 1) as a novel APPc-interacting protein. We found that the GULP1-APP interaction is mediated by the NPTY motif of APP and the GULP1 PTB (phosphotyrosine-binding) domain. Confocal microscopy revealed that a proportion of APP and GULP1 co-localized in neurons. In an APP-GAL4 reporter assay, we demonstrated that GULP1 altered the processing of APP. Moreover, overexpression of GULP1 enhanced the generation of APP CTFs (C-terminal fragments) and Aβ, whereas knockdown of GULP1 suppressed APP CTFs and Aβ production. The results of the present study reveal that GULP1 is a novel APP/APPc-interacting protein that influences APP processing and Aβ production.     

Prion protein interacts with BACE1 protein and differentially regulates its activity toward wild type and Swedish mutant amyloid precursor protein

In Alzheimer disease amyloid-β (Aβ) peptides derived from the amyloid precursor protein (APP) accumulate in the brain. Cleavage of APP by the β-secretase BACE1 is the rate-limiting step in the production of Aβ. We have reported previously that the cellular prion protein (PrP(C)) inhibited the action of BACE1 toward human wild type APP (APP(WT)) in cellular models and that the levels of endogenous murine Aβ were significantly increased in PrP(C)-null mouse brain. Here we investigated the molecular and cellular mechanisms underlying this observation. PrP(C) interacted directly with the prodomain of the immature Golgi-localized form of BACE1. This interaction decreased BACE1 at the cell surface and in endosomes where it preferentially cleaves APP(WT) but increased it in the Golgi where it preferentially cleaves APP with the Swedish mutation (APP(Swe)). In transgenic mice expressing human APP with the Swedish and Indiana familial mutations (APP(Swe,Ind)), PrP(C) deletion had no influence on APP proteolytic processing, Aβ plaque deposition, or levels of soluble Aβ or Aβ oligomers. In cells, although PrP(C) inhibited the action of BACE1 on APP(WT), it did not inhibit BACE1 activity toward APP(Swe). The differential subcellular location of the BACE1 cleavage of APP(Swe) relative to APP(WT) provides an explanation for the failure of PrP(C) deletion to affect Aβ accumulation in APP(Swe,Ind) mice. Thus, although PrP(C) exerts no control on cleavage of APP(Swe) by BACE1, it has a profound influence on the cleavage of APP(WT), suggesting that PrP(C) may be a key protective player against sporadic Alzheimer disease.     

Protein kinase C regulation of intracellular and cell surface amyloid precursor protein (APP) cleavage in CHO695 cells

Cleavage of amyloid precursor protein (APP) by beta-secretase generates beta-amyloid (Abeta), the major component of senile plaques in Alzheimer's disease. Cleavage of APP by alpha-secretase prevents Abeta formation, producing nonamyloidogenic secreted APPs products. PKC-regulated APP alpha-secretase cleavage has been shown to involve tumor necrosis factor alpha (TNF-alpha) converting enzyme (TACE). To determine the location of APP cleavage, we examined PKC-regulated APPs secretion by examining cell surface versus intracellular APP in CHO cells stably expressing APP(695) (CHO695). We demonstrate that PKC regulates cell surface and intracellular APP cleavage. The majority of secreted APPs originates from the intracellular compartment, and PKC does not cause an increase in APP trafficking to the cell surface for cleavage. Therefore, intracellular APP regulated by PKC must be cleaved at an intracellular site. Experiments utilizing Brefeldin A suggest APP cleavage occurs at the Golgi or late in the secretory pathway. Experiments using TAPI, an inhibitor of TACE, demonstrate PKC-regulated APPs secretion from the cell surface is inhibited after pretreatment with TAPI, and APPs secretion from the intracellular pool is partially inhibited after pretreatment with TAPI. These findings suggest PKC-regulated APP cleavage occurs at multiple locations within the cell and both events appear to involve TACE.     

Functions of Aβ, sAPPα and sAPPβ : similarities and differences

Amyloid peptide (Aβ) is derived from the cleavage of amyloid precursor protein (APP), which also generates the soluble peptide APPβ (sAPPβ). An antagonist and major APP metabolic pathway involves cleavage by alpha secretase, which releases sAPPα. Although soluble Aβ oligomers are neurotoxic, Aβ monomers share similar properties with sAPPα. These include neurotrophic and neuroprotective effects, as well as stimulation of neural-progenitor proliferation. The properties of Aβ monomers and the neurotrophic capacity of sAPPβ to stimulate axonal outgrowth suggest that Aβ production is not deleterious per se. Consequently, therapeutic strategies for Alzheimer's disease that are targeted at Aβ-cleaving enzymes should modulate rather than inhibit Aβ generation. These strategies should focus on the factors that induce the conversion of Aβ monomers into toxic soluble oligomers. Another interesting therapeutic approach is to focus on the mechanisms of the different properties of sAPPα. Indeed, increasing sAPPα levels could shift proliferating cells towards tumorigenesis. In contrast to its neuroprotective effects, sAPPα is also able to activate microglia, leading to neurotoxicity. Understanding the mechanisms that underlie the different properties of sAPPα could therefore lead to the development of therapeutic strategies against Alzheimer's disease, which could be curative as well as preventive.     

The amyloid precursor protein C-terminal fragment C100 occurs in monomeric and dimeric stable conformations and binds γ-secretase modulators

The amyloid-β (Aβ) peptide is contained within the C-terminal fragment (β-CTF) of the amyloid precursor protein (APP) and is intimately linked to Alzheimer's disease. In vivo, Aβ is generated by sequential cleavage of β-CTF within the γ-secretase module. To investigate γ-secretase function, in vitro assays are in widespread use which require a recombinant β-CTF substrate expressed in bacteria and purified from inclusion bodies, termed C100. So far, little is known about the conformation of C100 under different conditions of purification and refolding. Since C100 dimerization influences the efficiency and specificity of γ-secretase cleavage, it is also of great interest to determine the secondary structure and the oligomeric state of the synthetic substrate as well as the binding properties of small molecules named γ-secretase modulators (GSMs) which we could previously show to modulate APP transmembrane sequence interactions [Richter et al. (2010) Proc. Natl. Acad. Sci. U.S.A. 107, 14597-14602]. Here, we use circular dichroism and continuous-wave electron spin resonance measurements to show that C100 purified in a buffer containing SDS at micelle-forming concentrations adopts a highly stable α-helical conformation, in which it shows little tendency to aggregate or to form higher oligomers than dimers. By surface plasmon resonance analysis and molecular modeling we show that the GSM sulindac sulfide binds to C100 and has a preference for C100 dimers.     

ZnT3 mRNA levels are reduced in Alzheimer's disease post-mortem brain

Extensive genetic, biochemical, and histological evidence has implicated the amyloid-β peptide (Aβ) in Alzheimer's disease pathogenesis, and several mechanisms have been suggested, such as metal binding, reactive oxygen species production, and membrane pore formation. However, recent evidence argues for an additional role for signaling mediated by the amyloid precursor protein, APP, in part via the caspase cleavage of APP at aspartate 664. Here we review the effects and implications of this cleavage event, and propose a model of Alzheimer's disease that focuses on the critical nature of this cleavage and its downstream effects.     

BRI2 protein regulates β-amyloid degradation by increasing levels of secreted insulin-degrading enzyme (IDE)

The amyloid precursor protein (APP) is one of the major proteins involved in Alzheimer disease (AD). Proteolytic cleavage of APP gives rise to amyloid-β (Aβ) peptides that aggregate and deposit extensively in the brain of AD patients. Although the increase in levels of aberrantly folded Aβ peptide is considered to be important to disease pathogenesis, the regulation of APP processing and Aβ metabolism is not fully understood. Recently, the British precursor protein (BRI2, ITM2B) has been implicated in influencing APP processing in cells and Aβ deposition in vivo. Here, we show that the wild type BRI2 protein reduces plaque load in an AD mouse model, similar to its disease-associated mutant form, ADan precursor protein (ADanPP), and analyze in more detail the mechanism of how BRI2 and ADanPP influence APP processing and Aβ metabolism. We find that overexpression of either BRI2 or ADanPP reduces extracellular Aβ by increasing levels of secreted insulin-degrading enzyme (IDE), a major Aβ-degrading protease. This effect is also observed with BRI2 lacking its C-terminal 23-amino acid peptide sequence. Our results suggest that BRI2 might act as a receptor protein that regulates IDE levels that in turn influences APP metabolism in a previously unrecognized way. Targeting the regulation of IDE may be a promising therapeutic approach to sporadic AD.