BACE1 interacts with lipid raft proteins

A neuropathological hallmark of Alzheimer's disease is the presence of amyloid plaques in the brain. Amyloid-beta peptide (Abeta) is the major constituent of the plaques and is generated by proteolytic cleavages of amyloid precursor protein (APP) by beta- and gamma-secretases. Growing evidence shows that lipid rafts are critically involved in regulating the Abeta generation. In support of this, APP, Abeta, and presenilins have been found in lipid rafts. Although cholesterol plays a crucial role in maintaining lipid rafts, functions of other components in the generation of Abeta are unknown. Caveolins (CAVs) and flotillins (FLOTs) are principal proteins related to lipid rafts and have been suggested to be involved in APP processing. Here, we report that FLOT-1 binds to BACE1 (beta-site APP cleaving enzyme 1) and that overexpression of CAV-1 or FLOT-1 results in recruiting BACE1 into lipid rafts and influence on beta-secretase activity in cultured cells. Our results show that both CAV-1 and FLOT-1 may modulate beta-secretase activity by interacting with BACE1.     

Mechanisms of disease: new therapeutic strategies for Alzheimer's disease--targeting APP processing in lipid rafts

Alzheimer's disease (AD) is the most common cause of age-related dementia. Pathologically, AD is characterized by the deposition in the brain of amyloid-beta peptides derived from proteolysis of amyloid precursor protein (APP) by beta-site APP cleaving enzyme 1 (BACE1) and gamma-secretase. A growing body of evidence implicates cholesterol and cholesterol-rich membrane microdomains in amyloidogenic processing of APP. Here, we review recent findings regarding the association of BACE1, gamma-secretase and APP in lipid rafts, and discuss potential therapeutic strategies for AD that are based on knowledge gleaned from the membrane environment that fosters APP processing.     

BACE/APPV717F double-transgenic mice develop cerebral amyloidosis and inflammation

Most of the transgenic mice generated to model Alzheimer's disease express human amyloid precursor protein (APP) mutants alone or in conjunction with presenilin mutants. We have generated a mouse model by overexpressing human BACE and human APP with the V717F mutation. The combination of a mutation at the gamma-secretase cleavage site of APP and of increased beta-secretase activity should favour the production of amyloid peptides. We analysed double BACE/APPIn and single APPIn transgenic mice at 16-18 months for amyloid load, brain histopathology and behavioural deficits. We show that overexpression of BACE induces an increase in APP CTFbeta and total brain Abeta peptides. Brain histopathology shows clearly enhanced amyloid deposits in the cortex, hippocampus and in brain vasculature when compared to single APPIn transgenic mice. Amyloid deposits are mostly diffuse and predominantly composed of Abeta(42). A strong inflammatory reaction is evidenced by the presence of microglial cells around the most mature amyloid deposits and astrocytosis over the entire cerebral cortex. At the same age, the APPIn single-transgenic mice show only very limited pathology. When assessed for their cognitive performance at 12 months, BACE/APPIn mice show impaired spatial acquisition in the Morris water maze test. However, these deficits are not greater than those observed in the APPIn single-transgenic animals.     

BACE1: the beta-secretase enzyme in Alzheimer's disease

Data that have accumulated for well over a decade have implicated the beta-amyloid (Abeta) peptide as a central player in the pathogenesis of Alzheimer's disease (AD). Amyloid plaques, composed primarily of Abeta progressively form in the brains of AD patients, and mutations in three genes (amyloid precursor protein [APP] and presenilin 1 and 2 [PS1 and PS2]) cause early-onset familial AD (FAD) by directly increasing production of the toxic, plaque-promoting Abeta42 peptide. Given the strong association between Abeta and AD, it is likely that therapeutic strategies to lower the levels of Abeta in the brain should prove beneficial for the treatment of AD. One such strategy could involve inhibiting the enzymes that generate Abeta. Abeta is a product of catabolism of the large type-I membrane protein APP. Two proteases, called beta- and gamma-secretase, endoproteolyze APP to liberate the Abeta peptide. Recently, the molecules responsible for these proteolytic activities have been identified. Several lines of evidence suggest that the PS1 and PS2 proteins are gamma-secretase, and the identity of beta-secretase has been shown to be the novel transmembrane aspartic protease, beta-site APP-cleaving enzyme 1 (BACE1; also called Asp2 and memapsin 2). BACE2, a protease homologous to BACE1, was also identified, and together the two enzymes define a new family of transmembrane aspartic proteases. BACE1 exhibits all the functional properties of beta-secretase, and as the key enzyme that initiates the formation of Abeta, BACE1 is an attractive drug target for AD. This review discusses the identification and initial characterization of BACE1 and BACE2, and summarizes recent studies of BACE1 knockout mice that have validated BACE1 as the authentic beta-secretase in vivo.     

Proteolytic processing of the Alzheimer's disease amyloid precursor protein in brain and platelets

Proteolytic processing of the amyloid precursor protein by beta -and gamma-secretases results in the production of Alzheimer's disease (AD) Abeta amyloid peptides. Modulation of secretase activity is being investigated as a potential therapeutic approach. Recent studies with human brain have revealed that the beta-secretase protein, BACE, is increased in cortex of AD patients. Analysis of betaCTF (or C99), the amyloid precursor protein (APP) product of BACE cleavage that is the direct precursor to Abeta, shows it is also elevated in AD, underlying the importance of beta-secretase cleavage in AD pathogenesis. The C-terminal product of gamma-secretase cleavage of APP, epsilonCTF (or AICD), is enriched in human brain cortical nuclear fractions, a subcellular distribution appropriate for a putative involvement of APP cytosolic domain in signal transduction. Analysis of AD cortex samples, particularly that of a carrier of a familial APP mutation, suggests that processing of APP transmembrane domain generates an alternative CTF product. All these particularities observed in the AD brain demonstrate that APP processing is altered in AD. The transgenic mouse model Tg2576 seems to be a promising laboratory tool to test potential modulators of Abeta formation. Indeed, C-terminal products of alpha-, beta-, and gamma-secretase cleavage are readily detectable in the brain of these transgenic mice. Finally, the finding of the same secretase products in platelets and neurons make platelets a potentially useful and easily accessible clinical tool to monitor effects of novel therapies based on inhibition of beta- or gamma-secretase.     

Lactacystin decreases amyloid-beta peptide production by inhibiting beta-secretase activity

The human amyloid precursor protein (APP) is processed by the nonamyloidogenic and the amyloidogenic catabolic pathways. The sequential cleavage of APP by the beta- and gamma-secretase activities, known as the amyloidogenic processing of APP, leads to the formation of the amyloid-beta peptide (Abeta). Abeta is the main constituent of the amyloid core of senile plaques, a typical hallmark of Alzheimer's disease. In addition to secretases, other cellular proteolytic activities, like the proteasome, might participate in the metabolism of APP. We investigated the consequence of proteasome inhibition on the amyloidogenic processing of human APP. CHO cells and primary cultures of rat cortical neurons expressing human APP or a protein corresponding to its beta-cleaved C-terminal fragment (C99) were treated with lactacystin, an irreversible inhibitor of the chymotrypsin-like activity of the proteasome. Lactacystin significantly decreased the level of Abeta produced from APP in both cellular models, whereas the production of Abeta from C99 was not affected. Lactacystin did not inhibit gamma-secretase activity but was found to inhibit the beta-cleavage of APP, leading to a proportional decrease in Abeta production. Although lactacystin did not inhibit the catalytic activity of recombinant BACE1, a decrease in neuronal beta-secretase activity was measured after treatment with lactacystin.     

GM1 ganglioside regulates the proteolysis of amyloid precursor protein

Plaques containing amyloid beta-peptides (Abeta) are a major feature in Alzheimer's disease (AD), and GM1 ganglioside is an important component of cellular plasma membranes and especially enriched in lipid raft. GM1-bound Abeta (GM1/Abeta), found in brains exhibiting early pathological changes of AD including diffuse plaques, has been suggested to be involved in the initiation of amyloid fibril formation in vivo by acting as a seed. However, the role of GM1 in amyloid beta-protein precursor (APP) processing is not yet defined. In this study, we report that exogenous GM1 ganglioside promotes Abeta biogenesis and decreases sAPPalpha secretion in SH-SY5Y and COS7 cells stably transfected with human APP695 cDNA without affecting full-length APP and the sAPPbeta levels. We also observe that GM1 increases extracellular levels of Abeta in primary cultures of mixed rat cortical neurons transiently transfected with human APP695 cDNA. These findings suggest a regulatory role for GM1 in APP processing pathways.     

Relationship between beta amyloid peptide generating molecules and neprilysin in Alzheimer disease and normal brain

beta-Amyloid peptide (Abeta) is generated by two cleavages of amyloid precursor protein (APP). The initial cleavage by BACE is followed by gamma-secretase cleavage of the C-terminal APP fragment. Presenilin-1 (PS-1) is intimately related to gamma-secretase. Once formed, Abeta is mainly broken down by neprilysin. To estimate vulnerability to Abeta senile plaque formation, we measured the relative mRNA levels of APP695, APP751, APP770, BACE, presenilin-1 (PS-1) and neprilysin in nine brain areas and in heart, liver, spleen and kidney in a series of Alzheimer disease (AD) and control cases. Each of the mRNAs was expressed in every tissue examined. APP695 was the dominant APP isoform in brain. Compared with controls, APP695 and PS-1 mRNA levels were significantly elevated in high plaque areas of AD brain, while neprilysin mRNA levels were significantly reduced. BACE levels were not significantly different in AD compared with control brain. In peripheral organs, there were no significant differences in any of the mRNAs between AD and control cases. APP isoforms were differently expressed in the periphery than in brain, with APP 751>770>695. Neprilysin mRNA levels were much higher, while APP695 and PS-1 mRNA levels were much lower in the periphery than in brain. The data suggest that, in the periphery, the capacity to degrade Abeta is srong, accounting for the failure of Abeta deposits to form. In plaque prone areas of AD brain, the capacity to degrade Abeta is weak, while the capacity to generate Ab is upregulated. In plaque resistant areas of brain, a closer balance exists, but there is some tendency towards lower degrading and higher synthesizing capacity in AD brain compared with control brain. Overall, the data indicate that effectiveness of degradation by neprilysin may be a key factor in determining whether Abeta deposits develop.     

Cholesterol‐induced astrocyte activation is associated with increased amyloid precursor protein expression and processing

Cholesterol is essential for maintaining lipid raft integrity and has been regarded as a crucial regulatory factor for amyloidogenesis in Alzheimer's disease (AD). The vast majority of studies on amyloid precursor protein (APP) metabolism and amyloid β‐protein (Aβ) production have focused on neurons. The role of astrocytes remains largely unexplored, despite the presence of activated astrocytes in the brains of most patients with AD and in transgenic models of the disease. The role of cholesterol in Aβ production has been thoroughly studied in neurons and attributed to the participation of lipid rafts in APP metabolism. Thus, in this study, we analyzed the effect of cholesterol loading in astrocytes and analyzed the expression and processing of APP. We found that cholesterol exposure induced astrocyte activation, increased APP content, and enhanced the interaction of APP with BACE‐1. These effects were associated with an enrichment of ganglioside GM1‐cholesterol patches in the astrocyte membrane and with increased ROS production. GLIA 2015;63:2010–2022     

BACE1 structure and function in health and Alzheimer's disease

Amyloid plaques, hallmark neuropathological lesions in Alzheimer's disease (AD) brain, are composed of the beta-amyloid peptide (Abeta). Much evidence suggests that Abeta is central to the pathophysiology of AD and is likely to play an early role in this intractable neurodegenerative disorder. Given the strong correlation between Abeta and AD, therapeutic strategies to lower cerebral Abeta levels should prove beneficial for AD treatment. Abeta is derived from amyloid precursor protein (APP) via cleavage by two proteases, beta- and gamma-secretase. The beta-secretase has been identified as a novel aspartic protease named BACE1 (beta-site APP Cleaving Enzyme 1) that initiates Abeta formation. Importantly, BACE1 appears to be dysregulated in AD. As the rate-limiting enzyme in Abeta generation, BACE1, in principle, is an excellent therapeutic target for strategies to reduce the production of Abeta in AD. While BACE1 knockout (BACE1-/-) mice have been instrumental in validating BACE1 as the authentic beta-secretase in vivo, data indicates that complete abolishment of BACE1 may be associated with specific behavioral and physiological alterations. Recently a number of non-APP BACE1 substrates have been identified. It is plausible that failure to process certain BACE1 substrates may underlie some of the reported abnormalities in the BACE1-/- mice. Here we review the basic biology of BACE1, focusing on the regulation, structure and function of this enzyme. We pay special attention to the putative function of BACE1 during normal conditions and discuss in detail the relationship that exists between key risk factors for AD and the pathogenic alterations in BACE1 that are observed in the diseased state.     

Oligomerization of amyloid beta-protein occurs during the isolation of lipid rafts

Cholesterol- and glycosphingolipid-rich microdomains, called "lipid rafts," are suggested to initiate and promote the pathophysiology of Alzheimer's disease by serving as a platform for generation, aggregation, or degradation of amyloid-beta protein (Abeta). However, methods for biochemical isolation of these microdomains may produce artifacts. In this study, when synthetic Abeta1- 40 monomers were added to the brain fragment at a final concentration of 2.1 microM, followed by homogenization and isolation of lipid rafts by an established method, Abeta1- 40 accumulated as oligomers in the lipid raft fraction. However, in the absence of a brain homogenate, synthetic Abeta1- 40 did not accumulate in the lipid raft fraction. When fractionation was performed in the absence of synthetic Abeta1-40 and synthetic Abeta1-40 was incubated in an aliquot of each fraction, a marked oligomerization of Abeta1- 40 was observed in the lipid raft aliquot. These results indicate that exogenous Abeta associates with lipid rafts, and Abeta bound to rafts forms oligomers during the isolation of lipid rafts. In addition, endogenous Abeta1-40 in a Triton X-100-insoluble fraction of a brain homogenate of the Tg2576 transgenic mouse model of Alzheimer's disease formed oligomers when the fraction was incubated at 4 degrees C for 20 hr. Thus, one should be careful when one discusses the role of lipid rafts in amyloid precursor protein processing and in the generation, aggregation, and degradation of Abeta.     

Platelet amyloid precursor protein processing: a bio-marker for Alzheimer's disease

The amyloid precursor protein (APP) in brain is processed either by an amyloidogenic pathway by beta-secretase and gamma-secretase to yield Abeta (beta-amyloid 4 kDa) peptide or by alpha-secretase within the beta-amyloid domain to yield non-amyloidogenic products. We have studied blood platelet levels of a 22-kDa fragment containing the Abeta (beta-amyloid 4 kDa) peptide, beta-secretase (BACE1), alpha-secretase (ADAM10), and APP isoform ratios of the 120-130 kDa to 110 kDa peptides from 31 Alzheimer's disease (AD) patients and 10 age-matched healthy control subjects. We found increased levels of Abeta4, increased activation of beta-secretase (BACE1), decreased activation of alpha-secretase (ADAM10) and decreased APP ratios in AD patients compared to normal control subjects. These observations indicate that the blood platelet APP is processed by the same amyloidogenic and non-amyloidogenic pathways as utilized in brain and that APP processing in AD patients is altered compared to control subjects and may be a useful bio-marker for the diagnosis of AD, the progression of disease and for monitoring drug responses in clinical trials.     

GGA1 acts as a spatial switch altering amyloid precursor protein trafficking and processing

The beta-amyloid (Abeta) precursor protein (APP) is cleaved sequentially by beta-site of APP-cleaving enzyme (BACE) and gamma-secretase to release the Abeta peptides that accumulate in plaques in Alzheimer's disease (AD). GGA1, a member of the Golgi-localized gamma-ear-containing ARF-binding (GGA) protein family, interacts with BACE and influences its subcellular distribution. We now report that overexpression of GGA1 in cells increased the APP C-terminal fragment resulting from beta-cleavage but surprisingly reduced Abeta. GGA1 confined APP to the Golgi, in which fluorescence resonance energy transfer analyses suggest that the proteins come into close proximity. GGA1 blunted only APP but not notch intracellular domain release. These results suggest that GGA1 prevented APP beta-cleavage products from becoming substrates for gamma-secretase. Direct binding of GGA1 to BACE was not required for these effects, but the integrity of the GAT (GGA1 and TOM) domain of GGA1 was. GGA1 may act as a specific spatial switch influencing APP trafficking and processing, so that APP-GGA1 interactions may have pathophysiological relevance in AD.     

Human wild presenilin-1 mimics the effect of the mutant presenilin-1 on the processing of Alzheimer's amyloid precursor protein in PC12D cells

Most familial early-onset Alzheimer's disease (FAD) is caused by mutations in the presenilin-1 (PS1) gene. Abeta 42 is derived from amyloid precursor protein (APP) and increased concentrations are widely believed to be a pathological hallmark of abnormal PS function. Thus, the interaction between PS1 and APP is central to the molecular mechanism of AD. To examine the effect of wild-type human PS1 on rat APP metabolism, we made several PC12D cell lines that expressed human wild or mutant PS1, and analyzed the processing of endogenous rat APP and the intracellular gamma-secretase activity. We found the ratio of Abeta 42/Abeta 40 increased in PC12D cells expressing wild-type human PS1. These changes were identical to those found in PC12D cells expressing human PS1 bearing the A260V mutation. These results suggest that APP metabolism is physiologically regulated by the PS1 and that loss of normal PS1 affects gamma-secretase activity.     

Uncovering gamma-secretase

Accumulation of the amyloid beta-peptide (Abeta) in the brain is believed to initiate a series of neurotoxic events that causes neurodegeneration in Alzheimer's disease (AD). Abeta is generated by processing of the beta-amyloid precursor protein (APP) through the successive action of two proteolytic enzymes, beta-secretase and gamma-secretase. While beta-secretase has been identified as the membrane-bound aspartyl protease BACE, the identity of gamma-secretase, which catalyzes the final, intramembrane cleavage of APP as well as of several other type I transmembrane proteins, has been enigmatic for a long time. Exciting progress has been made in the past year towards its uncovering. Genetics paved the way for subsequent biochemical reconstitution studies that demonstrated that gamma-secretase is a protein complex composed of presenilin (PS), nicastrin (NCT), APH-1 and PEN-2. Thus, the complete set of genes that is required to generate Abeta from its precursor has now ultimately been identified. PS carries the active site of gamma-secretase and is a founding member of a novel class of polytopic aspartyl proteases that utilize a non-classical active site to cleave their membrane-tethered substrates. The other components are required for assembly, stabilization and maturation of the complex and NCT may be involved in the recognition of gamma-secretase substrates.     

Presenilin-1 interacts directly with the beta-site amyloid protein precursor cleaving enzyme (BACE1)

A neuropathological hallmark of Alzheimer's disease is the presence of amyloid plaques. The major constituent of these plaques, occurring largely in brain areas important for memory and cognition, is the 40-42 amyloid residues (Abeta). Abeta is derived from the amyloid protein precursor after cleavage by the recently identified beta-secretase (BACE1) and the putative gamma-secretase complex containing presenilin 1 (PS1). In an attempt to develop a functional secretase enzymatic assay in yeast we demonstrate a direct binding between BACE1 and PS1. This interaction was confirmed in vivo using coimmunoprecipitation and colocalization studies in human cultured cells. Our results show that PS1 preferably binds immature BACE1, thus possibly acting as a functional regulator of BACE1 maturation and/or activity.     

Cholesterol-dependent gamma-secretase activity in buoyant cholesterol-rich membrane microdomains

Buoyant membrane fractions containing presenilin 1 (PS1), an essential component of the gamma-secretase complex, and APP CTFbeta, a gamma-secretase substrate, can be isolated from cultured cells and brain by several different fractionation procedures that are compatible with in vitro gamma-secretase assays. Analysis of these gradients for amyloid beta protein (Abeta) and CTFgamma production indicated that gamma-secretase activity is predominantly localized in these buoyant membrane microdomains. Consistent with this localization, we find that gamma-secretase activity is cholesterol dependent. Depletion of membrane cholesterol completely inhibits gamma-secretase cleavage, which can be restored by cholesterol replacement. Thus, altering cholesterol levels may influence the development of Alzheimer's disease (AD) by influencing production and deposition of Abeta within cholesterol rich membrane microdomains.     

Control of amyloid-beta-peptide generation by subcellular trafficking of the beta-amyloid precursor protein and beta-secretase

Amyloid-beta (Abeta) peptides are major components of Alzheimer's disease (AD)-associated senile plaques and generated by sequential cleavage of the beta-amyloid precursor protein (betaAPP) by beta-secretase and gamma-secretase. While beta-secretase activity is exerted by the aspartic protease BACE1, gamma-secretase consists of a protein complex of at least four essential proteins with the presenilins as the catalytically active components. The understanding of the subcellular trafficking of betaAPP and proteases involved in its proteolytic processing has increased rapidly in the last years. BetaAPP as well as the secretases are membrane proteins, and recent work demonstrated that alterations in the lipid composition of cellular membranes could affect the proteolytic processing of betaAPP and Abeta generation. We identified glycosphingolipids as membrane components that modulate the subcellular transport of betaAPP and the generation of Abeta. By cell biological and biochemical methods we also characterized the role of BACE1 and its homologue BACE2 in the proteolytic processing of betaAPP. Here, I summarize and discuss these findings in the context of other studies focused on the function of BACE1 and BACE2 and the role of subcellular trafficking in the proteolytic processing of betaAPP.