Altered Amyloid Precursor Protein Processing Research Articles

Hypoxia increases Aβ generation by altering β- and γ-cleavage of APP

Environmental factors are significant contributors for the development of Alzheimer's disease (AD). The greatly increased incidence of AD following stroke and cerebral ischemia suggests that hypoxia is a risk factor which may accelerate AD pathogenesis by altering amyloid precursor protein (APP) processing. However, the molecular mechanisms underlying the hypoxia mediated AD pathogenesis have not been fully elucidated. In the present study we demonstrated that repeated hypoxia increased β-amyloid (Aβ) generation and neuritic plaques formation by elevating β-cleavage of APP in APP swe + PS1 A246E transgenic mice. We also found that hypoxia enhanced the expression of APH-1a, a component of γ-secretase complex, which in turn may lead to increase in γ-cleavage activity. Furthermore, we demonstrated that repeated hypoxia treatment can activate macroautophagy, which may contribute to the increases in Aβ production since pretreatment with macroautophagy inhibitor 3-methyladenine significantly blocked chemical hypoxic condition-induced increase in Aβ production in SH-SY5Y cells. Taken together, our results suggest an important role of hypoxia in modulating the APP processing by facilitating both β- and γ-cleavage which may result in a significant increase of Aβ generation.

The effect of stress on the expression of the amyloid precursor protein in rat brain

The abnormal processing of the amyloid precursor protein (APP) is a pivotal event in the development of the unique pathology that defines Alzheimer's disease (AD). Stress, and the associated increase in corticosteroids, appear to accelerate brain ageing and may increase vulnerability to Alzheimer's disease via altered APP processing. In this study, rats were repeatedly exposed to an unavoidable stressor, an open elevated platform. Previous studies in this laboratory have shown that a single exposure produces a marked increase in plasma corticosterone levels but animals develop tolerance to this effect between 10 and 20 daily sessions. Twenty-four hours after stress, there was an increase in the ratio of the deglycosylated form of APP in the particulate fraction of the brain, which subsequently habituated after 20 days. The levels of soluble APP (APPs) tended to be lower in the stress groups compared to controls except for a significant increase in the hippocampus after 20 days of platform exposure. Since APPs is reported to have neurotrophic properties, this increased release may represent a neuroprotective response to repeated stress. It is possible that the ability to mount this response decreases with age thus increasing the vulnerability to stress-induced AD-related pathology.

Platelet as a physiological model to investigate apoptotic mechanisms in Alzheimer β-amyloid peptide production

Although neuronal apoptosis in Alzheimer's disease is generally interpreted as the consequence of the toxicity of extracellular β-amyloid (Aβ) peptide aggregates, some experimental results provide evidence that the Aβ overproduction can be the result of a primary neuronal degeneration. As platelets are considered a good model where to study proteolytic processing of the amyloid precursor protein (APP), we exposed platelets to the proapoptotic agent ionomycin and analyzed Aβ40 and Aβ42 levels in the intracellular and extracellular compartments. The activation of apoptotic pathways in platelets has been verified by mitochondrial membrane depolarization, exposure of phosphatidylserine, protease activation and morphological changes. A significative increase in intraplatelet Aβ40, but not Aβ42, was observed after 10 min treatment with ionomycin. Thus, the activation of apoptotic pathways in platelets determines an altered processing of APP leading to elevated levels of intracellular Aβ40. The specific intracellular production of Aβ40 represents a potential threat to the cells since very high local Aβ40 concentration increases the risk of its aggregation and toxicity. As a result, Aβ40 might be dangerous even before it becomes secreted rendering neurons highly vulnerable.

The FE65 proteins and Alzheimer's disease

The FE65s (FE65, FE65L1, and FE65L2) are a family of multidomain adaptor proteins that form multiprotein complexes with a range of functions. FE65 is brain-enriched, whereas FE65L1 and FE65L2 are more widely expressed. All three members contain a WW domain and two PTB domains. Through the PTB2 domain, they all interact with the Alzheimer's disease amyloid precursor protein (APP) intracellular domain (AICD) and can alter APP processing. After sequential proteolytic processing of membrane-bound APP and release of AICD to the cytoplasm, FE65 can translocate to the nucleus to participate in gene transcription events. This role is further mediated by interactions of FE65 PTB1 with the transcription factors CP2/LSF/LBP1 and Tip60 and the WW domain with the nucleosome assembly factor SET. However, FE65 target genes have not yet been confirmed. The FE65 PTB1 domain also interacts with two cell surface lipoproteins receptors, the low-density lipoprotein receptor-related protein (LRP) and ApoEr2, forming trimeric complexes with APP. The FE55 WW domain also binds to mena, through which it functions in regulation of the actin cytoskeleton, cell motility, and neuronal growth cone formation. While single knockout mice appear normal, double FE65(-/-)/FE65L1(-/-) mice have substantial neurodevelopmental defects. These include heterotopic neurons and axonal pathfinding defects, findings similar to findings in both Mena and triple APP:APLP1:APLP2 knockout mice and also lissencephalopathies in humans. Thus APPs, FE65s, and mena may act together in a developmental signalling pathway. This article reviews the known functions of the FE65 family and their role in APP function and Alzheimer's disease.

Docosahexaenoic acid stimulates non‐amyloidogenic APP processing resulting in reduced Aβ levels in cellular models of Alzheimer's disease

Epidemiological studies suggest that a high intake of polyunsaturated fatty acids, such as docosahexaenoic acid (DHA), is associated with a reduced risk of Alzheimer's disease. Here, we examined the effects of DHA on amyloid precursor protein (APP) processing in cellular models of Alzheimer's disease by analysing levels of different APP fragments, including amyloid-beta (Abeta). DHA administration stimulated non-amyloidogenic APP processing and reduced levels of Abeta, providing a mechanism for the reported beneficial effects of DHA in vivo. However, an increased level of APP intracellular domain was also observed, highlighting the need to increase our knowledge about the relevance of this fragment in Alzheimer's disease pathogenesis. In conclusion, our results suggest that the proposed protective role of DHA in Alzheimer's disease pathogenesis might be mediated by altered APP processing and Abeta production.

The Arctic Alzheimer mutation favors intracellular amyloid‐β production by making amyloid precursor protein less available to α‐secretase

Mutations within the amyloid-beta (Abeta) domain of the amyloid precursor protein (APP) typically generate hemorrhagic strokes and vascular amyloid angiopathy. In contrast, the Arctic mutation (APP E693G) results in Alzheimer's disease. Little is known about the pathologic mechanisms that result from the Arctic mutation, although increased formation of Abeta protofibrils in vitro and intraneuronal Abeta aggregates in vivo suggest that early steps in the amyloidogenic pathway are facilitated. Here we show that the Arctic mutation favors proamyloidogenic APP processing by increased beta-secretase cleavage, as demonstrated by altered levels of N- and C-terminal APP fragments. Although the Arctic mutation is located close to the alpha-secretase site, APP harboring the Arctic mutation is not an inferior substrate to a disintegrin and metalloprotease-10, a major alpha-secretase. Instead, the localization of Arctic APP is altered, with reduced levels at the cell surface making Arctic APP less available for alpha-secretase cleavage. As a result, the extent and subcellular location of Abeta formation is changed, as revealed by increased Abeta levels, especially at intracellular locations. Our findings suggest that the unique clinical symptomatology and neuropathology associated with the Arctic mutation, but not with other intra-Abeta mutations, could relate to altered APP processing with increased steady-state levels of Arctic Abeta, particularly at intracellular locations.

Altered Subcellular Distribution of the Alzheimer's Amyloid Precursor Protein Under Stress Conditions

Altered metabolism of the Alzheimer's amyloid precursor protein (APP) appears to be a key event in the pathogenesis of Alzheimer's disease (AD), and both altered phosphorylation and oxidative stress appear to affect the production of the toxic Abeta fragment. Our results show that altered processing of APP was observed under conditions of stress induced by sodium azide in the presence of 2-deoxy-D-glucose (2DG). As previously reported, the production of the secreted fragment of APP (sAPP) was inhibited. Using APP-GFP fusion proteins, we show that 2DG causes the accumulation/delay of APP in the endoplasmic reticulum (ER)/Golgi (G). The 751 isoform accumulated preferentially in the G, whereas the 695 isoform was blocked preferentially at the ER. This effect was augmented in the presence of sodium azide. APP subcellular distribution was also affected at the plasma membrane. The involvement of protein phosphorylation in APP subcellular localization was reinforced by the effect of drugs, such as phorbol 12-myristate 13-acetate (PMA), since APP was completely depleted from the membrane in the presence of 2DG and PMA. Thus, the hypothesis that APP is processed in a phosphorylation-dependent manner and that this may be of clinical relevance appears to hold true even under stress conditions. Our results provide evidence for a role of protein phosphorylation in APP sorting under stress conditions and contribute to the understanding of the molecular basis of AD.

FAD mutants unable to increase neurotoxic Aβ 42 suggest that mutation effects on neurodegeneration may be independent of effects on Aβ

Strong support for a primary causative role of the Abeta peptides in the development of Alzheimer's disease (AD) neurodegeneration derives from reports that presenilin familial AD (FAD) mutants alter amyloid precursor protein processing, thus increasing production of neurotoxic Abeta 1-42 (Abeta 42). This effect of FAD mutants is also reflected in an increased ratio of peptides Abeta 42 over Abeta 1-40 (Abeta 40). In the present study, we show that several presenilin 1 FAD mutants failed to increase production of Abeta 42 or the Abeta 42/40 ratio. Our data suggest that the mechanism by which FAD mutations promote neurodegeneration and AD may be independent of their effects on Abeta production.

Cat and Mouse

The role of cathepsin B, a lysosomal protease implicated in amyloid-beta (Abeta1-42) metabolism, in Alzheimer's disease remains controversial. In this issue of Neuron, Mueller-Steiner et al. manipulate the expression of cathepsin B in aged APP transgenic mice, observing that increased expression degrades preformed oligomeric and fibrillar amyloid, while inactivation accelerates beta-amyloidosis.

BACE1 inhibition reduces endogenous Abeta and alters APP processing in wild‐type mice2

Accumulation of amyloid beta peptide (Abeta) in brain is a hallmark of Alzheimer's disease (AD). Inhibition of beta-site amyloid precursor protein (APP)-cleaving enzyme-1 (BACE1), the enzyme that initiates Abeta production, and other Abeta-lowering strategies are commonly tested in transgenic mice overexpressing mutant APP. However, sporadic AD cases, which represent the majority of AD patients, are free from the mutation and do not necessarily have overproduction of APP. In addition, the commonly used Swedish mutant APP alters APP cleavage. Therefore, testing Abeta-lowering strategies in transgenic mice may not be optimal. In this study, we investigated the impact of BACE1 inhibition in non-transgenic mice with physiologically relevant APP expression. Existing Abeta ELISAs are either relatively insensitive to mouse Abeta or not specific to full-length Abeta. A newly developed ELISA detected a significant reduction of full-length soluble Abeta 1-40 in mice with the BACE1 homozygous gene deletion or BACE1 inhibitor treatment, while the level of x-40 Abeta was moderately reduced due to detection of non-full-length Abeta and compensatory activation of alpha-secretase. These results confirmed the feasibility of Abeta reduction through BACE1 inhibition under physiological conditions. Studies using our new ELISA in non-transgenic mice provide more accurate evaluation of Abeta-reducing strategies than was previously feasible.

Degradation of the Alzheimer Disease Amyloid β-Peptide by Metal-dependent Up-regulation of Metalloprotease Activity

Biometals play an important role in Alzheimer disease, and recent reports have described the development of potential therapeutic agents based on modulation of metal bioavailability. The metal ligand clioquinol (CQ) has shown promising results in animal models and small phase clinical trials; however, the actual mode of action in vivo has not been determined. We now report a novel effect of CQ on amyloid beta-peptide (Abeta) metabolism in cell culture. Treatment of Chinese hamster ovary cells overexpressing amyloid precursor protein with CQ and Cu(2+) or Zn(2+) resulted in an approximately 85-90% reduction of secreted Abeta-(1-40) and Abeta-(1-42) compared with untreated controls. Analogous effects were seen in amyloid precursor protein-overexpressing neuroblastoma cells. The secreted Abeta was rapidly degraded through up-regulation of matrix metalloprotease (MMP)-2 and MMP-3 after addition of CQ and Cu(2+). MMP activity was increased through activation of phosphoinositol 3-kinase and JNK. CQ and Cu(2+) also promoted phosphorylation of glycogen synthase kinase-3, and this potentiated activation of JNK and loss of Abeta-(1-40). Our findings identify an alternative mechanism of action for CQ in the reduction of Abeta deposition in the brains of CQ-treated animals and potentially in Alzheimer disease patients.

The Common Inhalation Anesthetic Isoflurane Induces Apoptosis and Increases Amyloid β Protein Levels

The common inhalation anesthetic isoflurane has previously been reported to enhance the aggregation and cytotoxicity of the Alzheimer disease-associated amyloid beta protein (Abeta), the principal peptide component of cerebral beta-amyloid deposits. H4 human neuroglioma cells stably transfected to express human full-length wild-type amyloid precursor protein (APP) were exposed to 2% isoflurane for 6 h. The cells and conditioned media were harvested at the end of the treatment. Caspase-3 activation, processing of APP, cell viability, and Abeta levels were measured with quantitative Western blotting, cell viability kit, and enzyme-linked immunosorbent assay sandwich. The control condition consisted of 5% CO2 plus 21% O2 and balanced nitrogen, which did not affect caspase-3 activation, cell viability, APP processing, or Abeta generation. Two percent isoflurane caused apoptosis, altered processing of APP, and increased production of Abeta in H4 human neuroglioma cell lines. Isoflurane-induced apoptosis was independent of changes in Abeta and APP holoprotein levels. However, isoflurane-induced apoptosis was potentiated by increased levels of APP C-terminal fragments. A clinically relevant concentration of isoflurane induces apoptosis, alters APP processing, and increases Abeta production in a human neuroglioma cell line. Because altered processing of APP leading to accumulation of Abeta is a key event in the pathogenesis of Alzheimer disease, these findings may have implications for use of this anesthetic agent in individuals with excessive levels of cerebral Abeta and elderly patients at increased risk for postoperative cognitive dysfunction.

Caveolin-1 upregulation in senescent neurons alters amyloid precursor protein processing

Lipid rafts provide a platform for regulating cellular functions and participate in the pathogenesis of several diseases. However, the role of caveolin-1 in this process has not been elucidated definitely in neuron. Thus, this study was performed to examine whether caveolin-1 can regulate amyloid precursor protein (APP) processing in neuronal cells and to identify the molecular mechanisms involved in this regulation. Caveolin-1 is up-regulated in all parts of old rat brain, namely hippocampus, cerebral cortex and in elderly human cerebral cortex. Moreover, detergent-insoluble glycolipid (DIG) fractions indicated that caveolin-1 was co-localized with APP in caveolae-like structures. In DIG fractions, beta APP secretion was up-regulated by caveolin-1 over- expression, which was modulated via protein kinase C (PKC) in neuroblastoma cells. From these results we conclude that caveolin-1 is selectively expressed in senescent neurons and that it induces the processing of APP by beta-secretase via PKC downregulation.

3,4-Methylenedioxymethamphetamine (MDMA), but not morphine, alters APP processing in the rat brain

The abuse of drugs such as opioids and 3,4-methylenedioxymethamphetamine (MDMA or 'ecstasy') can have detrimental effects on the cognitive functions, but the exact molecular mechanism whereby these drugs promote neurodegeneration remains to be elucidated. The major purpose of the present pilot study was to determine whether the chronic in-vivo administration of morphine (10 mg/kg) or MDMA (1 mg/kg) to rats can alter the expression and processing of amyloid precursor protein (APP), the central molecule in the proposed pathomechanism of Alzheimer's disease. MDMA treatment significantly decreased the production of APP in the cytosolic fraction of the brain cortex. A concomitant 25% increase was found both in the beta-secretase (BACE) and APP mRNA levels (108%). In contrast, in the applied single dosage chronic morphine treatment did not influence either the APP and BACE protein levels or the APP mRNA production. These results indicate that the chronic use of 'ecstasy', but not morphine, may be harmful via a novel mode of action, i.e. by altering the APP expression and processing in the brain.

Cholesterol Distribution, Not Total Levels, Correlate With Altered Amyloid Precursor Protein Processing in Statin-Treated Mice

There are now a number of studies that suggest that cholesterol might regulate the processing of the amyloid precursor protein to form the neurotoxic peptide Abeta. This research has opened the possibility that cholesterol-lowering drugs might be efficacious as anti-Abeta drugs for use in Alzheimer's disease. The use of HMG-CoA reductase inhibitors (commonly called statins) in vitro and in vivo has proven them to be Abeta-lowering agents, however, the mechanism of action of these drugs is not yet known. One possible mechanism is that they reduce Abeta levels indirectly by reducing cholesterol in the central nervous system (CNS). In this study, we administered three different statins (simvastatin, lovastatin, and atorvastatin) to nontransgenic mice. We found that all three compounds had similar effects on Abeta, reducing both Abeta40 and Abeta42. The statins decreased beta-cleaved C-terminal fragment (CTF) although having no effect on alpha-CTF levels. However, the drugs did not have a similar effect on cholesterol in the CNS. Only lovastatin significantly reduced total cholesterol in isolated plasma membranes. As cholesterol is not distributed evenly in the plasma membrane, we examined bilayer distribution of cholesterol and found that all three statins caused CNS cholesterol to translocate from the cytofacial leaflet to the exofacial leaflet. This data suggests that cholesterol distribution and not total cholesterol levels may be important to Abeta production in the CNS.

ε-Glycation, APP and Aβ in ageing and Alzheimer disease: A hypothesis

The post-translational modifications of protein molecules include glycation, which may not only occur enzymatically controlled in N and O position, but also wherever proteins meet reducing sugars non-enzymatically in epsilon position at lysines (non-enzymatic (epsilon) glycation (NEG)). The formation of keto-amines from the amine-sugar compounds (Amadori re-arrangement) and further processing of the largely undigestible Amadori compounds eventually results in insoluble advanced glycation end products (AGEs). The latter can induce or favour disease including mental disorders. Preferential targets of NEG include large cell surface proteins. Ample evidence has been provided that NEG also occurs in the brain where cross-linking of epsilon-glycated proteins, induction of oxidative stress and signalling of AGEs through their specific receptor (RAGE) likely play a role in (brain) ageing and Alzheimer disease (AD). This is underscored by the demonstration of particular interactions between AGE/RAGE and amyloid-beta (Abeta) that favour the aggregation and deposition of Abeta and, perhaps, the formation of Abeta itself. The close relationship between NEG and Abeta, as well as other facts foster the hypothesis that NEG of the large trans-membrane amyloid precursor protein (APP) might be a significant factor in the induction of aberrant APP cleavage with production of Abeta, not only in normal ageing, but also in AD. Blockade of lysine cleavage sites on APP by sugar chains or marker effects induced by NEG akin to ubiquitination of proteins for degradation at lysines could be expected to contribute to altered processing of APP. The hypothesis of epsilon-glycation in APP proposed here and the review of evidences for the significance of NEG in brain ageing and AD are aimed at the stimulation of investigations into the still open question which role NEG plays with respect to APP and its abnormal processing in AD. It can be rendered likely that such research might open new avenues towards decreasing the risk of AD and/or slowing its progression through the prevention of NEG in APP with aberrant APP processing, increased generation of Abeta and the formation of AGEs from epsilon-glycated APP.

Sequences from the Low Density Lipoprotein Receptor-related Protein (LRP) Cytoplasmic Domain Enhance Amyloid β Protein Production via the β-Secretase Pathway without Altering Amyloid Precursor Protein/LRP Nuclear Signaling

Increasing evidence suggests that the low density lipoprotein receptor-related protein (LRP) affects the processing of amyloid precursor protein (APP) and amyloid beta (Abeta) protein production as well as mediates the clearance of Abeta from the brain. Recent studies indicate that the cytoplasmic domain of LRP is critical for this modulation of APP processing requiring perhaps a complex between APP, the adaptor protein FE65, and LRP. In this study, we expressed a small LRP domain consisting of the C-terminal 97 amino acids of the cytoplasmic domain, or LRP-soluble tail (LRP-ST), in CHO cells to test the hypothesis that the APP.LRP complex can be disrupted. We anticipated that LRP-ST would inhibit the normal interaction between LRP and APP and therefore perturb APP processing to resemble a LRP-deficient state. Surprisingly, CHO cells expressing LRP-ST demonstrated an increase in both sAPP secretion and Abeta production compared with control CHO cells in a manner reminiscent of the cellular effects of the APP "Swedish mutation." The increase in sAPP secretion consisted mainly of sAPPbeta, consistent with the increase in Abeta release. Further, this effect is LRP-independent, as the same alterations remained when LRP-ST was expressed in LRP-deficient cells but not when the construct was membrane-anchored. Finally, deletion experiments suggested that the last 50 amino acid residues of LRP-ST contain the important domain for altering APP processing and Abeta production. These observations indicate that there are cellular pathways that may suppress Abeta generation but that can be altered to facilitate Abeta production.

β-amyloid 42 accumulation in the lumbar spinal cord motor neurons of amyotrophic lateral sclerosis patients

Amyotrophic lateral sclerosis (ALS) is characterized by a progressive loss of large motor neurons in the brain and spinal cord. Amyloid precursor protein (APP), the transmembrane precursor of beta-amyloid (A beta), accumulates in the anterior horn motor neurons of ALS patients with mild lesions. APP undergoes an alternative proteolysis mediated by caspase-3, which is activated in motor neurons in a mouse model of ALS. The ALS spinal cord motor neurons also show evidence of increased oxidative damage, which is thought to alter APP processing. We sought to determine whether A beta42, the more pathogenic A beta species, accumulates in the postmortem lumbar spinal cord of ALS patients. While there was little or no A beta42 labeling in control spinal cord tissues, elevated A beta42 immunoreactivity occurred in ALS motor neuronal perikarya and axonal swellings in the anterior horn. A few A beta42-positive neurons exhibited thioflavine S staining. No extracellular A beta42 deposits were found. A beta42 coexisted with the oxidative damage markers malondialdehyde, 8-hydroxydeoxyguanosine, heme oxygenase-1, and nitrotyrosine in abnormal neurons. The neurons with intracellular A beta42 accumulation also displayed robust cleaved caspase-3 immunoreactivity. Very little A beta40 immunoreactivity occurred in motor neurons of both control and ALS. These results suggest that aberrant accumulation of A beta42 in ALS spinal cord motor neurons is associated with oxidative stress, and may play a role in the pathogenesis of neurodegeneration in ALS.

Molecular Rationale for the Pharmacological Treatment of Alzheimer??s Disease

Cerebral deposition of amyloid plaques containing amyloid beta-peptide (Abeta) has traditionally been considered the central feature of Alzheimer's disease (AD). Abeta is derived from amyloid precursor protein (APP), which is cleaved by several different proteases: alpha-, beta- and gamma-secretase. In the past decade, however, the molecular pathogenesis of AD has been shown to involve alterations in several neurotransmitter, inflammatory, oxidative, and hormonal pathways that represent potential targets for AD prevention and treatment. Much research has shown a direct link between cholinergic impairment and altered APP processing as a major pathogenetic event in AD. Three highly probable mechanisms of APP regulation through inhibition of acetylcholinesterase are thus current topics of investigation. Indeed, acetylcholinesterase inhibitors appear to cause selective muscarinic activation of alpha-secretase and to induce the translation of APP mRNA; they may also restrict amyloid fibre assembly. Activation of N-methyl-D-aspartate receptors is considered a probable cause of chronic neurodegeneration in AD, and memantine has been widely used in some countries in AD patients to block cerebral N-methyl-D-aspartate receptors that normally respond to glutamate. Further studies are needed to determine whether antioxidants such as vitamins C and E are effective, through various mechanisms, in patients with mild-to-moderate AD. Additional data are also required for non-steroidal anti-inflammatory drugs, some of which appear to possess experimental effects that may ultimately prove favourable in AD patients. Statins also warrant further investigation, since they have activated alpha-secretase and they reduced Abeta generation and amyloid accumulation in a transgenic mouse model. beta-Secretase would seem to be an ideal target for anti-amyloid therapy in AD, but potential clinical and pharmacological issues, such as ensuring selectivity of inhibition, stability, and ease of blood-brain barrier penetration and cellular uptake, remain to be addressed for beta-secretase inhibitors. gamma-Secretase is not an easy candidate for pharmacological manipulation. Immunotherapeutic strategies have targeted Abeta directly; however, intensive investigation of indirect approaches to the management of AD with immunotherapy is now underway.

Prion protein (PrP c) promotes β-amyloid plaque formation

Prion protein (PrP) has been localized to amyloid-beta (Aβ) senile plaques in aging and Alzheimer disease, but it is unknown whether PrP is directly involved in plaque formation or represents a reaction to amyloid deposition. To evaluate possible functional effects of PrP in Aβ plaque formation, we analyzed bigenic mice (TgCRND8/Tg7), carrying mutant human amyloid precursor protein (APP) 695 (APP Swed + Ind , TgCRND8) as well as the wild-type Syrian hamster prion protein gene (sHaPrP, Tg7), showing Aβ plaques at 3 months of age as well as highly increased HaPrP c levels. Compared to the control group, consisting of animals carrying only mutant APP, bigenic mice showed a higher number of senile plaques in the cerebral cortex, while APP transcription and Aβ40/Aβ42 levels were unchanged. Double-labelling immunofluorescence showed co-localization of Aβ and PrP in virtually all plaques in the brains of both control and experimental animals. Our data suggest that PrP promotes plaque formation, and that this hitherto unknown functional role of PrP appears to be mediated by increased Aβ aggregation rather than by altered APP transcription or processing.