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.     

Proteasome-mediated degradation of the C-terminus of the Alzheimer's disease beta-amyloid protein precursor: effect of C-terminal truncation on production of beta-amyloid protein

The beta-amyloid protein (Abeta) is derived by proteolytic processing of the amyloid protein precursor (APP). Cleavage of APP by beta-secretase generates a C-terminal fragment (APP-CTFbeta), which is subsequently cleaved by gamma-secretase to produce Abeta. Our previous studies have shown that the proteasome can cleave the C-terminal cytoplasmic domain of APP. To identify proteasome cleavage sites in APP, two peptides homologous to the C-terminus of APP were incubated with recombinant 20S proteasome. Cleavage of the peptides was monitored by reversed phase high-performance liquid chromatography and mass spectrometry. Proteasome cleaved the APP C-terminal peptides at several sites, including a region around the sequence YENPTY that interacts with several APP-binding proteins. To examine the effect of this cleavage on Abeta production, APP-CTFbeta and mutant forms of APP-CTFbeta terminating on either side of the YENPTY sequence were expressed in CHO cells. Truncation of APP-CTFbeta on the N-terminal side of the YENPTY sequence at residue 677 significantly decreased the amount of Abeta produced, whereas truncation on the C-terminal side of residue 690 had little effect. The results suggest that proteasomal cleavage of the cytosolic domain of APP at the YENPTY sequence decreases gamma-secretase processing, and consequently inhibits Abeta production. Therefore, the proteasome-dependent trafficking pathway of APP may be a valid therapeutic target for altering Abeta production in the Alzheimer's disease brain.     

Calcium ionophore A23187 specifically decreases the secretion of beta-secretase cleaved amyloid precursor protein during apoptosis in primary rat cortical cultures

Alzheimer's disease (AD) is characterized by the degeneration and loss of neurons, intracellular neurofibrillary tangles and the accumulation of extracellular senile plaques consisting mainly of beta-amyloid (A beta). A beta is generated from the amyloid precursor protein (APP) by sequential beta- and gamma-secretase cleavage. Alternatively, APP may be cleaved within the A beta region by alpha-secretase, preventing A beta formation. Here we investigated APP processing and secretion in primary neurons, using either colchicine or the calcium ionophore A23187 to induce apoptosis. Cell viability was determined by MTT measurements and apoptosis was further confirmed by annexin V and propidium iodide staining. We found that exposure to A23187 significantly decreased the secretion of soluble beta-secretase cleaved APP (beta-sAPP) in a caspase-dependent manner, although the secretion of total soluble APP beta sAPP) did not change. In addition, caspase inhibition restored cell viability to control levels. Exposure to colchicine did not change the amount of either secreted beta-sAPP or total sAPP and caspase inhibition was only partially able to restore cell viability. We conclude that calcium homeostasis is an important apoptotic effector specifically affecting the beta-secretase cleavage of APP.     

Genetic programming by the proteolytic fragments of the amyloid precursor protein: somewhere between confusion and clarity

Mice engineered to overexpress disease-causing mutant amyloid precursor proteins (APP) display plaque deposition, but lack the hyperphosphorylated tau and massive neuronal loss characteristic of Alzheimer's disease (AD). Global gene expression profiles of brain regions from AD patients show upregulation of proapoptotic and inflammatory genes and down-regulation of neurotrophic, MAPK, phosphatase, and synaptic genes, while a profile of mice overexpressing a mutant APP shows the opposite trends in apoptotic and neurotrophic genes. The proteolytic fragments of the amyloid precursor protein have distinct biological actions. Both the gamma-secretase cleaved COOH-terminal fragment (CTFgamma) and the alpha-secretase cleaved NH2-terminal of APP (sAPPalpha) can regulate gene expression. While Abeta and CTFgamma can lead to toxicity and cell death, sAPPalpha promotes neurite outgrowth, enhances memory, and protects against a variety of insults, including Abeta toxicity. In AD, Abeta levels increase while sAPPalpha levels decrease. These subtleties in the levels of APP cleavage products are not reproduced in mice overexpressing mutant APP. In fact, the gene expression changes driven by sAPPalpha, such as increases in transthyretin and insulin-like growth factor 2, may protect these mice from high levels of Abeta.     

Beta-secretase protein and activity are increased in the neocortex in Alzheimer disease

CONTEXT: Amyloid plaques, a major pathological feature of Alzheimer disease (AD), are composed of an internal fragment of amyloid precursor protein (APP): the 4-kd amyloid-beta protein (Abeta). The metabolic processing of APP that results in Abeta formation requires 2 enzymatic cleavage events, a gamma-secretase cleavage dependent on presenilin, and a beta-secretase cleavage by the aspartyl protease beta-site APP-cleaving enzyme (BACE). OBJECTIVE: To test the hypothesis that BACE protein and activity are increased in regions of the brain that develop amyloid plaques in AD. METHODS: We developed an antibody capture system to measure BACE protein level and BACE-specific beta-secretase activity in frontal, temporal, and cerebellar brain homogenates from 61 brains with AD and 33 control brains. RESULTS: In the brains with AD, BACE activity and protein were significantly increased (P<.001). Enzymatic activity increased by 63% in the temporal neocortex (P =.007) and 13% in the frontal neocortex (P =.003) in brains with AD, but not in the cerebellar cortex. Activity in the temporal neocortex increased with the duration of AD (P =.008) but did not correlate with enzyme-linked immunosorbent assay measures of insoluble Abeta in brains with AD. Protein level was increased by 14% in the frontal cortex of brains with AD (P =.004), with a trend toward a 15% increase in BACE protein in the temporal cortex (P =.07) and no difference in the cerebellar cortex. Immunohistochemical analysis demonstrated that BACE immunoreactivity in the brain was predominantly neuronal and was found in tangle-bearing neurons in AD. CONCLUSIONS: The BACE protein and activity levels are increased in brain regions affected by amyloid deposition and remain increased despite significant neuronal and synaptic loss in AD.     

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.     

Presenilin I expression in yeast lowers secretion of the amyloid precursor protein

Presenilin (PS) mutations are associated with early-onset Alzheimer's disease and PS proteins are involved with gamma-secretase cleavage of the amyloid precursor protein, APP. We have shown previously that alpha-, beta- and gamma-secretase cleavages of APP are conserved in Pichia pastoris. Here, we report co-expression of APP and PSI in P. pastoris and show by immunoelectron microscopy colocalization of these two proteins in expanded endoplasmic reticulum. Western blot analysis indicates a drastic reduction of both alpha- and beta-secretase products. A relative increase in beta-secretase product derived from immature APP is also observed, pointing to a beta-secretase activity of P. pastoris associated with the early secretory pathway.     

A comparative assessment of gamma-secretase activity in transgenic and non-transgenic rodent brain

Amyloid-beta (Abeta) deposits are one of the hallmarks of the neuropathological degeneration observed in Alzheimer's disease (AD) and Abeta concentrations have been reported to vary in different brain regions of AD patients. Abeta is produced by the sequential cleavage of amyloid precursor protein (APP) by beta-secretase and gamma-secretase, respectively. Previous studies have shown that over-expression of the gamma-secretase complex leads to increased gamma-secretase proteolytic activity increasing Abeta production. However, it is not known whether brain regions with highest Abeta concentration also express relatively higher levels of gamma-secretase activity. Accordingly, the relationship between Abeta levels and gamma-secretase activity across brain regions was investigated and correlated in the brains of transgenic and non-transgenic rodents commonly used in AD research. The data demonstrated that Abeta levels do vary in different brain regions in both transgenic and non-transgenic mice but are not correlated with regional gamma-secretase activity. Furthermore, this study demonstrated that while mutations in the APP and PS1 sequences affect the absolute Abeta levels this is not reflected in an increase in gamma-secretase proteolytic activity. The data in the current paper indicate that this assay is able to measure the level of gamma-secretase activity in rodent species. Using this methodology will aid our understanding of physiological gamma-secretase function.     

From presenilinase to gamma-secretase, cleave to capacitate

Mutations in two genes, presenilin 1 (PS1) and its homologue presenilin 2 (PS2), account for a majority of early onset familial Alzheimer disease cases which are characterized by intracellular neurofibrillary tangles and extracellular amyloid fibrils composed of the amyloid beta protein (Abeta). Abeta is derived from sequential cleavages of Amyloid Precursor Protein (APP) by beta-secretase and gamma-secretase, the latter is composed of four components, PS1, nicastrin (NCT), presenilin enhancer 2 (PEN-2), and anterior pharynx defective (APH-1). These components not only maintain the stability of the gamma-secretase complex but also regulate the activity of presenilinase, the protease responsible for the cleavage of full length PS1 into N-terminal and C-terminal fragments (NTF/CTF). We have previously shown that endoproteolysis of PS1 into NTF/CTF by presenilinase requires two critical aspartate residues, suggesting that PS1 may undergo autoproteolysis; full length PS1 complexes with NCT, PEN-2, APH-1 and forms the presenilinase. While these two aspartate residues are necessary for the endoproteolysis of full length PS1, they are equally critical for the gamma-secretase cleavage of multiple substrates, and it is hypothesized that the full length PS1/presenilinase is the zymogen of gamma-secretase. The inhibition profiles of presenilinase and gamma-secretase are illustrated by their biochemical similarity but are pharmacologically distinct. Since the uncleaved PS1 loop may obstruct the entry of gamma-secretase substrates to the docking site of the gamma-secretase complex, investigation of presenilinase inhibitors interfering with substrate-docking may facilitate a novel approach to identify APP specific gamma-secretase inhibitors.     

Aging increased amyloid peptide and caused amyloid plaques in brain of old APP/V717I transgenic mice by a different mechanism than mutant presenilin1.

Aging of transgenic mice that overexpress the London mutant of amyloid precursor protein (APP/V717I) (Moechars et al., 1999a) was now demonstrated not to affect the normalized levels of alpha- or beta-cleaved secreted APP nor of the beta-C-terminal stubs. This indicated that aging did not markedly disturb either alpha- or beta-secretase cleavage of APP and failed to explain the origin of the massive amounts of amyloid peptides Abeta40 and Abeta42, soluble and precipitated as amyloid plaques in the brain of old APP/V717I transgenic mice. We tested the hypothesis that aging acted on presenilin1 (PS1) to affect gamma-secretase-mediated production of amyloid peptides by comparing aged APP/V717I transgenic mice to double transgenic mice coexpressing human PS1 and APP/V717I. In double transgenic mice with mutant (A246E) but not wild-type human PS1, brain amyloid peptide levels increased and resulted in amyloid plaques when the mice were only 6-9 months old, much earlier than in APP/V717I transgenic mice (12-15 months old). Mutant PS1 increased mainly brain Abeta42 levels, whereas in aged APP/V717I transgenic mice, both Abeta42 and Abeta40 increased. This resulted in a dramatic difference in the Abeta42/Abeta40 ratio of precipitated or plaque-associated amyloid peptides, i.e., 3.11+/-0.22 in double APP/V717I x PS1/A246E transgenic mice compared with 0.43 +/- 0.07 in aged APP/V717I transgenic mice, and demonstrated a clear difference between the effect of aging and the effect of the insertion of a mutant PS1 transgene. In conclusion, we demonstrate that aging did not favor amyloidogenic over nonamyloidogenic processing of APP, nor did it exert a mutant PS1-like effect on gamma-secretase. Therefore, the data are interpreted to suggest that parenchymal and vascular accumulation of amyloid in aging brain resulted from failure to clear the amyloid peptides rather than from increased production.     

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.     

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.     

Caspase inhibition therapy abolishes brain trauma-induced increases in Abeta peptide: implications for clinical outcome

The detrimental effects of traumatic brain injury (TBI) on brain tissue integrity involve progressive axonal damage, necrotic cell loss, and both acute and delayed apoptotic neuronal death due to activation of caspases. Post-injury accumulation of amyloid precursor protein (APP) and its toxic metabolite amyloid-beta peptide (Abeta) has been implicated in apoptosis as well as in increasing the risk for developing Alzheimer's disease (AD) after TBI. Activated caspases proteolyze APP and are associated with increased Abeta production after neuronal injury. Conversely, Abeta and related APP/Abeta fragments stimulate caspase activation, creating a potential vicious cycle of secondary injury after TBI. Blockade of caspase activation after brain injury suppresses apoptosis and improves neurological outcome, but it is not known whether such intervention also prevents increases in Abeta levels in vivo. The present study examined the effect of caspase inhibition on post-injury levels of soluble Abeta, APP, activated caspase-3, and caspase-cleaved APP in the hippocampus of nontransgenic mice expressing human Abeta, subjected to controlled cortical injury (CCI). CCI produced brain tissue damage with cell loss and elevated levels of activated caspase-3, Abeta(1-42) and Abeta(1-40), APP, and caspase-cleaved APP fragments in hippocampal neurons and axons. Post-CCI intervention with intracerebroventricular injection of 100 nM Boc-Asp(OMe)-CH(2)F (BAF, a pan-caspase inhibitor) significantly reduced caspase-3 activation and improved histological outcome, suppressed increases in Abeta and caspase-cleaved APP, but showed no significant effect on overall APP levels in the hippocampus after CCI. These data demonstrate that after TBI, caspase inhibition can suppress elevations in Abeta. The extent to which Abeta suppression contributes to improved outcome following inhibition of caspases after TBI is unclear, but such intervention may be a valuable therapeutic strategy for preventing the long-term evolution of Abeta-mediated pathology in TBI patients who are at risk for developing AD later in life.     

Ectodomain shedding of the amyloid precursor protein: cellular control mechanisms and novel modifiers

Proteolytic cleavage in the ectodomain of the amyloid precursor protein (APP) is a key regulatory step in the generation of the Alzheimer's disease amyloid-beta (Abeta) peptide and occurs through two different protease activities termed alpha- and beta-secretase. Both proteases compete for APP cleavage, but have opposite effects on Abeta generation. At present, little is known about the cellular pathways that control APP alpha- or beta-secretase cleavage and thus Abeta generation. To explore the contributory pathways in more detail we have recently employed an expression cloning screen and identified several activators of APP cleavage by alpha- or beta-secretase. Among them were known activators of APP cleavage, for example protein kinase A, and novel activators, such as endophilin and the APP homolog amyloid precursor-like protein 1 (APLP1). Mechanistic analysis revealed that both endophilin and APLP1 reduce the rate of APP endocytosis and strongly increase APP cleavage by alpha-secretase. This review summarizes the results of the expression cloning screen in the context of recent developments in our understanding of the cellular regulation of APP alpha-secretase cleavage. Moreover, it highlights the particular importance of endocytic APP trafficking as a prime modulator of APP shedding.     

Mechanisms of cell death in Alzheimer's disease: role of presenilins

Presenilins are often mutated in familial forms of Alzheimer's disease (AD). Such mutations sensitize cells in culture to different apoptotic stimuli eg. staurosporine, calcium ionophore, growth factor withdrawal. The altered responses to apoptotic stimuli in cells carrying presenilin mutations include increased intracellular calcium concentrations and enhanced production of reactive oxygen species. Presenilin mutations also result in increased production of amyloid beta (Abeta) indicating that presenilins participate in the cleavage of amyloid beta-protein precursor (AbetaPP). In fact, presenilin is part of the gamma-secretase complex which together with beta-secretase cleaves AbetaPP and produce Abeta, later forming the senile plaques typical for AD pathology. Here we review the current knowledge about the mechanisms of cell death in AD with focus on the role of presenilin and presenilin mutations in apoptosis. It appears that presenilin and its different fragments, generated after proteolytic cleavage, have a regulatory role in apoptosis. In addition, different studies show that the cellular levels of presenilin are controlled by proteasomal degradation both under normal and stress conditions.     

Beta-secretase: structure, function, and evolution

The most popular current hypothesis is that Alzheimer's disease (AD) is caused by aggregates of the amyloid peptide (Abeta), which is generated by cleavage of the Abeta protein precursor (APP) by beta-secretase (BACE-1) followed by gamma-secretase. BACE-1 cleavage is limiting for the production of Abeta, making it a particularly good drug target for the generation of inhibitors that lower Abeta. A landmark discovery in AD was the identification of BACE-1 (a.k.a. Memapsin-2) as a novel class of type I transmembrane aspartic protease. Although BACE-2, a homologue of BACE-1, was quickly identified, follow up studies using knockout mice demonstrated that BACE-1 was necessary and sufficient for most neuronal Abeta generation. Despite the importance of BACE-1 as a drug target, development has been slow due to the incomplete understanding of its function and regulation and the difficulties in developing a brain penetrant drug that can specifically block its large catalytic pocket. This review summarizes the biological properties of BACE-1 and attempts to use phylogenetic perspectives to understand its function. The article also addresses the challenges in discovering a selective drug-like molecule targeting novel mechanisms of BACE-1 regulation.     

JLK inhibitors: isocoumarin compounds as putative probes to selectively target the gamma-secretase pathway

Alzheimer's disease is characterized by the extracellular deposition of the amyloid beta-peptide that derives from its precursor betaAPP by sequential actions of beta- and gamma- secretases, respectively. Recent studies aimed at identifying these enzymes have been reported as it is thougth that their inhibition should hopefully lead to reduce Abeta load in the AD brains. beta-secretase seems to be due to BACE1, a novel membrane-bound aspartyl protease. gamma-secretase identification is still a matter of controversy. Invalidation of presenilin genes was reported to impair both gamma-secretase-mediated Abeta production and Notch cleavage leading to NICD production. This observation together with another biochemical and pharmacological evidences led to suggest that presenilins could be the genuine long-searched gamma-secretase that would be responsible for both APP and Notch cleavages. We have designed novel non peptidic potential inhibitors of gamma-secretase (referred to as JLK inhibitors) and examined their ability to prevent Abeta40 and Abeta42 secretions as well as NICD production. Three out of a series of these agents drastically lower the recoveries of both Abeta40 and Abeta42 produced by betaAPP-expressing cell lines and concomitantly protect intracellular C99 and C83 recoveries. These inhibitors also prevent Abeta40/42 productions by C99-expressing cells. Interestingly, these inhibitors were totally unable to affect the DeltaENotch cleavage leading to NICD generation. Here, we also further characterize the pharmacological properties and specificity of these JLK inhibitors.     

Evidence for caspase-mediated cleavage of AMPA receptor subunits in neuronal apoptosis and Alzheimer's disease.

In Alzheimer's disease (AD) synapses degenerate and neurons die in brain regions involved in learning and memory processes. Although the cellular and molecular mechanisms underlying the neurodegenerative process in AD are unclear, increasing evidence suggests roles for amyloid beta-peptide (Abeta) and biochemical cascades associated with a form of programmed cell death called apoptosis. Cysteine proteases of the caspase family are activated in neurons undergoing apoptosis and apparently play a major role in the cell death process by cleaving yet-to-be-identified substrates. We now report that caspase activity is increased in brain tissue and neurons from AD patients, and in cultured hippocampal neurons undergoing apoptosis after exposure to amyloid beta-peptide (Abeta). Western blot analyses using antibodies against different subunits of 2-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) and N-methyl-D-aspartate (NMDA) types of ionotropic glutamate receptors indicate that AMPA receptor subunits (GluR1, GluR2/3, and GluR4), but not NMDA receptor subunits (NR1 and NR2A), are proteolytically cleaved after exposure of hippocampal neurons to apoptotic insults, including Abeta, and that the caspase inhibitor zVAD-fmk suppresses such cleavage. Western blot analysis of brain tissue from AD patients and age-matched controls revealed evidence for increased proteolysis of AMPA receptor subunits in AD. Our data suggest roles for caspase-mediated cleavage of AMPA receptor subunits in modifying neuronal responsivity to glutamate and in the neurodegenerative process in AD.     

Amyloid precursor protein compartmentalization restricts β-amyloid production

Alzheimer's disease (AD) is defined by deposits of the 42-residue amyloid-beta peptide (Abeta42) in the brain. Abeta42 is a minor metabolite of the amyloid precursor protein (APP), but its relative levels are increased by mutations on APP and presenilins 1 and 2 linked to familial AD. beta-secretase (BACE-1), an aspartyl protease, cleaves approx 10% of the APP in neuronal cells on the N-terminal side of Abeta to produce the C-terminal fragment (CTFbeta), which is cleaved by gamma-secretase to produce mostly Abeta of 40 residues (90%) and approx10% Abeta42. A third enzyme, alpha-secretase, cleaves APP after Abeta16 to secrete sAPPalpha and CTFalpha, the major metabolites of APP. Moreover, previous studies have demonstrated that phorbol esters stimulate processing of APP by alpha-secretase. Because alpha-secretase and BACE-1 cleave APP within the secretory pathway, it is likely that the two enzymes compete for the APP substrate. This type of competition can explain the failure to saturate the minor BACE-1 pathway by overexpressing APP in the cell. In this study, we demonstrate that inhibition of constitutive alpha-secretase processing in a human neuroblastoma cell line does not increase the yield of Abeta, suggesting that the APP substrate targeted for alpha-secretase processing is not diverted to the BACE-1 pathway. However, when phorbol ester-induced alpha-secretase was similarly inhibited, we detected an increase in BACE-1 processing and AB yield. We explain these results compartmentalization of BACE-1 and alpha-secretase with processing depending on sorting of APP to the two compartments. The simplest explanation for the detection of competition between the two pathways upon phorbol ester stimulation is the partial failure of this compartmentalization by phorbol ester-induced release of secretory vesicles.