Overexpression of amyloid precursor protein induces susceptibility to oxidative stress in human neuroblastoma SH-SY5Y cells

Summary. In Alzheimer’s disease amyloid β peptide (Aβ) produced from amyloid precursor protein (APP) is considered to induce cell death. To clarify the molecular mechanism underlying Aβ neurotoxicity, we established the cell line overexpressing wild or mutant (His684Arg) APP in human SH-SY5Y cells. This paper presents that overexpression of wild-APP in the cells (SH/w-APP) increased the levels of APP and Aβ_1–40 but not Aβ_1–42, and reduced Bcl-2 level and proteasome activity with increased susceptibility to oxidative stress. The intracellular levels of reactive oxygen species in SH/w-APP increased significantly by H₂O₂ treatment. The level of Bcl-2 protein, but not mRNA, was markedly decreased in SH/w-APP cells, which was inversely correlated with APP expression among subcloned SH/w-APP cells. These results indicate that increased expression of wild type APP renders neuronal cells more vulnerable to oxidative stress leading to cell death.     

Association of membrane-bound amyloid precursor protein APP with the apolipoprotein E receptor LRP

In order to identify cell surface proteins that interact with the amyloid precursor protein (APP), we biotinylated H4 human neuroglioma cells in culture with a water soluble biotinylating agent, immunoprecipitated APP with an antibody specific to the intracellular domain, and probed the precipitated proteins with anti-biotin. In human neuroglioma cells overexpressing APP751, we found a high molecular weight protein that immunoprecipitated with APP. This band was identified as the low density lipoprotein receptor-related protein (LRP) by three criteria: first, the band immunolabeled with anti-LRP antibodies; second, the band bound the LRP receptor associated protein, RAP; and third, this band was present in LRP-expressing fibroblasts, but not LRP-deficient fibroblasts. In complementary experiments, we found that APP co-precipitated with LRP, with a preference for an isoform of APP containing the Kunitz protease inhibitor domain. Interaction of APP and LRP on the surface of living cells was demonstrated by crosslinking APP and LRP with the water-soluble cross-linking agent BS(3). APP and LRP were shown by confocal microscopy to colocalize in perinuclear structures, but to primarily remain separate in vesicles and on the cell surface. We propose that full-length APP can transiently interact with the receptor LRP on the cell surface, affecting the processing and intracellular transport of APP.     

Axonopathy in an APP/PS1 transgenic mouse model of Alzheimer’s disease

While axonopathy is a prominent feature in a variety of neurodegenerative diseases, it has been largely neglected in Alzheimer’s disease (AD), despite the observation of frequent motoric deficits in AD patients. In the present report we used transgenic mice overexpressing human mutant β-amyoid precursor protein (APP^751SL) and presenilin-1 (PS1^M146L) that exhibit elevated intraneuronal Aβ42 levels. We observed abundant age-dependent axonopathy in the spinal cord: axons immunopositive for ubiquitin in the dorsal column; axonal swellings (spheroids) which accumulated APP, neurofilament, and ubiquitin; as well as myelin ovoid structures, which serve as markers for nerve fiber degeneration in both white and gray matter. Both descending and ascending axonal tracts in white matter were affected. Neuritic plaques also developed in an age-dependent manner starting in the cervical region. Furthermore, early intraneuronal Aβ was detected in some but not all motor neurons before plaque formation. In the present APP/PS1 transgenic mouse model we could show for the first time that elevated intracellular Aβ levels lead to an axonopathy characterized by the formation of axonal spheroids and myelin ovoids. The same pathological alterations are known from AD patients or transgenic models overexpressing Tau or ApoE, however, these disturbances in axonal transport occur in the absence of any signs of concomitant Tau pathology. This strengthens the prevailing amyloid hypothesis as a primary trigger of AD-typical pathological alterations.Oliver Wirths and Joachim Weis contributed equally.     

Overexpression of human cystatin C in transgenic mice does not affect levels of endogenous brain amyloid β peptide

Cystatin C, an inhibitor of cysteine proteases, colocalizes with amyloid β (Aβ) in parenchymal and vascular amyloid deposits in brains of Alzheimer’s disease (AD) patients, suggesting that cystatin C has a role in AD. Cystatin C also colocalizes with β amyloid precursor protein (βAPP) in transfected cultured cells. In vitro analysis of the association between the two proteins revealed that binding of cystatin C to full-length βAPP does not affect the level of Aβ secretion. Here we studied the effect of in vivo overexpression of cystatin C on the levels of endogenous brain Aβ. We have generated lines of transgenic mice expressing either wild-type human cystatin C or the Leu68Gln variant that forms amyloid deposits in the cerebral vessels of Icelandic patients with hereditary cerebral hemorrhage, under control sequences of the human cystatin C gene. Western blot analysis of brain homogenates was used to select lines of mice expressing various levels of the transgene. Analysis of Aβ40 and Aβ42 concentrations in the brain showed no difference between transgenic mice and their nontransgenic littermates. Thus, in vivo overexpression of human cystatin C does not affect Aβ levels in mice that do not deposit Aβ.     

Comparison of Pharmacological Modulation of APP Metabolism in Primary Chicken Telencephalic Neurons and in a Human Neuroglioma Cell Line

Sequential cleavage of amyloid precursor protein (APP) by β- and γ-secretases and the formation of Aβ peptides are pivotal for Alzheimer's disease. Therefore, a large number of drugs has been developed targeting APP metabolism. However, many pharmacological compounds have been identified in vitro in immortalized APP overexpressing cell lines rather than in primary neurons. Here, we compared the effect of already characterized secretase inhibitors and modulators on Aβ formation in primary chicken telencephalic neurons and in a human neuroglioma cell line (H4) ectopically expressing human APP with the Swedish double mutation. Primary chicken neurons replicated the effects of a β-secretase inhibitor (β-secretase inhibitor IV), two γ-secretase inhibitors (DAPM, DAPT), two non-steroidal-anti-inflammatory drugs (sulindac sulfide, CW), and of the calpain inhibitor calpeptin. With the exception of the two γ-secretase inhibitors, all tested compounds were more efficacious in primary chicken telencephalic neurons than in the immortalized H4 cell line. Moreover, H4 cells failed to reproduce the effect of calpeptin. Hence, primary chicken telencephalic neurons represent a suitable cell culture model for testing drugs interfering with APP processing and are overall more sensitive to pharmacological interference than immortalized H4 cells ectopically expressing mutant human APP.     

LRP1 modulates APP trafficking along early compartments of the secretory pathway

The amyloid beta peptide (Aβ) is a central player in Alzheimer's disease (AD) pathology. Aβ liberation depends on APP cleavage by β- and γ-secretases. The low density lipoprotein receptor related protein 1 (LRP1) was shown to mediate APP processing at multiple steps. Newly synthesized LRP1 can interact with APP, implying an interaction between these two proteins early in the secretory pathway. We wanted to investigate whether LRP1 mediates APP trafficking along the secretory pathway, and, if so, whether it affects APP processing. Indeed, the early trafficking of APP within the secretory pathway is strongly influenced by its interaction with the C-terminal domain of LRP1. The LRP1-construct expressing an ER-retention motif, LRP-CT KKAA, had the capacity to retard APP traffic to early secretory compartments. In addition, we provide evidence that APP metabolism occurs in close conjunction with LRP1 trafficking, highlighting a new role of lipoprotein receptors in neurodegenerative diseases.     

Advances in the cellular and molecular biology of the beta-amyloid protein in Alzheimer's disease

Alzheimer’s disease (AD) is a progressive senile dementia characterized by deposition of a 4 kDa peptide of 39–42 residues known as amyloid beta-peptide (Aβ) in the form of senile plaques and the microtubule associated protein tau as paired helical filaments. Genetic studies have identified mutations in the Aβ precursor protein (APP) as the key triggers for the pathogenesis of AD. Other genes such as presenilins 1 and 2 (PS1/2) and apolipoprotein E (APOE) also play a critical role in increased Aβ deposition. Several biochemical and molecular studies using transfected cells and transgenic animals point to mechanisms by which Aβ is generated and aggregated to trigger the neurodegeneration that may cause AD. Three important enzymes collectively known as “secretases” participate in APP processing. An enzymatic activity, β-secretase, cleaves APP on the amino side of Aβ producing a large secreted derivative, sAPPβ, and an Aβ-bearing membrane-associated C-terminal derivative, CTFβ, which is subsequently cleaved by the second activity, γ-secretase, to release Aβ. Alternatively, a third activity, α-secretase, cleaves APP within Aβ to the secreted derivative sAPPα and membrane-associated CTFα. The predominant secreted APP derivative is sAPPα in most cell-types. Most of the secreted Aβ is 40 residues long (Aβ40) although a small percentage is 42 residues in length (Aβ42). However, the longer Aβ42 aggregates more readily and was therefore considered to be the pathologically important form. Advances in our understanding of APP processing, trafficking, and turnover will pave the way for better drug discovery for the eventual treatment of AD. In addition, APP gene regulation and its interaction with other proteins may provide useful drug targets for AD. The emerging knowledge related to the normal function of APP will help in determining whether or not the AD associated changes in APP metabolism affect its function. The present review summarizes our current understanding of APP metabolism and function and their relationship to other proteins involved in AD.     

Small heat shock protein HspB8: its distribution in Alzheimer’s disease brains and its inhibition of amyloid-β protein aggregation and cerebrovascular amyloid-β toxicity

Alzheimer’s disease (AD) is characterized by pathological lesions, such as senile plaques (SPs) and cerebral amyloid angiopathy (CAA), both predominantly consisting of a proteolytic cleavage product of the amyloid-β precursor protein (APP), the amyloid-β peptide (Aβ). CAA is also the major pathological lesion in hereditary cerebral hemorrhage with amyloidosis of the Dutch type (HCHWA-D), caused by a mutation in the gene coding for the Aβ peptide. Several members of the small heat shock protein (sHsp) family, such as αB-crystallin, Hsp27, Hsp20 and HspB2, are associated with the pathological lesions of AD, and the direct interaction between sHsps and Aβ has been demonstrated in vitro. HspB8, also named Hsp22 of H11, is a recently discovered member of the sHsp family, which has chaperone activity and is observed in neuronal tissue. Furthermore, HspB8 affects protein aggregation, which has been shown by its ability to prevent formation of mutant huntingtin aggregates. The aim of this study was to investigate whether HspB8 is associated with the pathological lesions of AD and HCHWA-D and whether there are effects of HspB8 on Aβ aggregation and Aβ-mediated cytotoxicity. We observed the expression of HspB8 in classic SPs in AD brains. In addition, HspB8 was found in CAA in HCHWA-D brains, but not in AD brains. Direct interaction of HspB8 with Aβ_1–42, Aβ_1–40 and Aβ_1–40 with the Dutch mutation was demonstrated by surface plasmon resonance. Furthermore, co-incubation of HspB8 with D-Aβ_1–40 resulted in the complete inhibition of D-Aβ_1–40-mediated death of cerebrovascular cells, likely mediated by a reduction in both the β-sheet formation of D-Aβ_1–40 and its accumulation at the cell surface. In contrast, however, with Aβ_1–42, HspB8 neither affected β-sheet formation nor Aβ-mediated cell death. We conclude that HspB8 might play an important role in regulating Aβ aggregation and, therefore, the development of classic SPs in AD and CAA in HCHWA-D.     

Intraneuronal pyroglutamate-Abeta 3–42 triggers neurodegeneration and lethal neurological deficits in a transgenic mouse model

It is well established that only a fraction of Aβ peptides in the brain of Alzheimer’s disease (AD) patients start with N-terminal aspartate (Aβ_1D) which is generated by proteolytic processing of amyloid precursor protein (APP) by BACE. N-terminally truncated and pyroglutamate modified Aβ starting at position 3 and ending with amino acid 42 [Aβ_3(pE)–42] have been previously shown to represent a major species in the brain of AD patients. When compared with Aβ_1–42, this peptide has stronger aggregation propensity and increased toxicity in vitro. Although it is unknown which peptidases remove the first two N-terminal amino acids, the cyclization of Aβ at N-terminal glutamate can be catalyzed in vitro. Here, we show that Aβ_3(pE)–42 induces neurodegeneration and concomitant neurological deficits in a novel mouse model (TBA2 transgenic mice). Although TBA2 transgenic mice exhibit a strong neuronal expression of Aβ_3–42 predominantly in hippocampus and cerebellum, few plaques were found in the cortex, cerebellum, brain stem and thalamus. The levels of converted Aβ_3(pE)-42 in TBA2 mice were comparable to the APP/PS1KI mouse model with robust neuron loss and associated behavioral deficits. Eight weeks after birth TBA2 mice developed massive neurological impairments together with abundant loss of Purkinje cells. Although the TBA2 model lacks important AD-typical neuropathological features like tangles and hippocampal degeneration, it clearly demonstrates that intraneuronal Aβ_3(pE)–42 is neurotoxic in vivo.     

Amyloid-β protein modulates the perivascular clearance of neuronal apolipoprotein E in mouse models of Alzheimer’s disease

The deposition of amyloid-β protein (Aβ) in the brain is a hallmark of Alzheimer’s disease (AD). Apolipoprotein E (apoE) is involved in the clearance of Aβ from brain and the APOE ε4 allele is a major risk factor for sporadic AD. We have recently shown that apoE is drained into the perivascular space (PVS), where it co-localizes with Aβ. To further clarify the role of apoE in perivascular clearance of Aβ, we studied apoE-transgenic mice over-expressing human apoE4 either in astrocytes (GE4) or in neurons (TE4). These animals were crossbred with amyloid precursor protein (APP)-transgenic mice and with APP-presenilin-1 (APP-PS1) double transgenic mice. Using an antibody that specifically detects human apoE (h-apoE), we observed that astroglial expression of h-apoE in GE4 mice leads to its perivascular drainage, whereas neuronal expression in TE4 mice does not, indicating that neuron-derived apoE is usually not the subject of perivascular drainage. However, h-apoE was observed not only in the PVS of APP-GE4 and APP-PS1-GE4 mice, but also in that of APP-TE4 and APP-PS1-TE4 mice. In all these mouse lines, we found co-localization of neuron-derived h-apoE and Aβ in the PVS. Aβ and h-apoE were also found in the cytoplasm of perivascular astrocytes indicating that astrocytes take up the neuron-derived apoE bound to Aβ, presumably prior to its clearance into the PVS. The uptake of apoE–Aβ complexes into glial cells was further investigated in glioblastoma cells. It was mediated by α₂macroglobulin receptor/low density lipoprotein receptor-related protein (LRP-1) and inhibited by adding receptor-associated protein (RAP). It results in endosomal Aβ accumulation within these cells. These results suggest that neuronal apoE–Aβ complexes, but not neuronal apoE alone, are substrates for LRP-1-mediated astroglial uptake, transcytosis, and subsequent perivascular drainage. Thus, the production of Aβ and its interaction with apoE lead to the pathological perivascular drainage of neuronal apoE and provide insight into the pathological interactions of Aβ with neuronal apoE metabolism.     

Endogenous overproduction of β-amyloid induces tau hyperphosphorylation and decreases the solubility of tau in N2a cells

Summary. Although neurofibrillary tangles and senile plaques have been identified as the hallmark pathological changes in the brain of Alzheimer’s disease (AD), the relationship between them is still not fully understood. In the present study, we have studied the effect of endogenously overproduced amyloid β (Aβ) on tau by using wild type amyloid precursor protein (APP) transfected (N2a/APP695), or Swedish mutant APP plus Δ9 deleted presenilin-1 co-transfected (N2a/APPswe.Δ9) and APP vector transfected (N2a/vector) cell lines. We measured the secreted and intracellular Aβ, including Aβ_1–40 and Aβ_1–42, by Sandwich ELISA assay. It was shown that the levels of Aβ were increased time-dependently in N2a/APP695 and N2a/APPswe.Δ9 but not in N2a/vector upon butyric acid (BA) treatment. Compared with N2a/vector cells, tau in N2a/APP695 and N2a/APPswe.Δ9 cells was not extracted by RIPA buffer, and the SDS-extracted tau protein was hyperphosphorylated at Tau-1 and PHF-1 epitopes upon BA treatment. Obvious accumulation of the hyperphosphorylated tau in N2a/APP695 and N2a/APPswe.Δ9 cells was observed at 48 h after BA treatment. The total level of the extracted tau was reduced in N2a/APP695 and N2a/APPswe.Δ9 lines compared with N2a/vector cells by Western blot, and this reduction of total tau was also detected by immunofluorescence staining. No obvious alteration of tau mRNA was observed in both N2a/APP695 and N2a/APPswe.Δ9 cells compared with N2a/vector. This study provides direct evidence demonstrating that endogenously overproduced Aβ not only induces tau hyperphosphorylation but also decreases the level and solubility of tau in N2a cell lines. The first and second authors contributed equally to the paper     

Deposition of amyloid β protein (Aβ) subtypes [Aβ40 and Aβ42(43)] in canine senile plaques and cerebral amyoloid angiopathy

To clarify the immunohistochemical features of canine senile plaques (SPs) and cerebral amyloid angiopathy (CAA), the distribution of the amyloid β protein (Aβ) subtypes Aβ40 and Aβ42(43), Aβ precursor protein (APP), and glial cell reaction were examined in the brains of seven aged dogs (12–18 years). Aβ42(43) was found to be deposited in all types of SPs, whereas Aβ40 was deposited only in mature (classical and primitive) plaques. CAA, which was located along parenchymal and meningeal arterioles and capillaries, consisted of both subtypes of Aβ. APP was exhibited in normal and degenerative neurons and swollen neurites of mature plaques. It was, therefore, considered that Aβ42(43) in diffuse plaques might be derived from APP in neurons, while Aβ40 and Aβ42(43) in mature plaques might be generated from APP in swollen neurites in the plaque. In contrast to the case in humans, in whom deposition of Aβ40 and Aβ42(43) in the mature plaques is predominantly associated with microglial reaction, in dogs we found that it was closely associated with astroglial reaction. The present findings showed characteristics of canine SPs which are different from those of humans. Received: 11 October 1996 / Revised: 27 March 1997, 10 April 1997 / Accepted: 10 April 1997     

Localizations of endogenous APP/APP-Proteolytic products are consistent with microtubular transport

Dementia of the Alzheimer type (DAT) is associated with the accumulation of β-amyloid (Aβ) peptides derived from β-amyloid precursor protein (APP). Goldstein and coworkers have suggested that APP acts as a cargo receptor connecting post-Golgi vesicles and motor proteins. Sisodia and colleagues have suggested that APP is a passive passenger within the vesicles. Both views predict that one should be able to visualize colocalizations of APP with microtubules, the object of the present investigation. To avoid possible artifacts created by APP overexpression, we studied endogenous expression in a human neuroblas toma cell line (SK-N-SH). Using high-resolution fluorescence microscopy and antibodies specific for the amino termini of APP and Aβ sequences, we found that endogenous APP and Aβ peptide immunoreactivities colocalized with microtubules in interphase cells. Disruption of microtubules, followed by fixation at various time points during repolymerization, allowed us to observe the sequence and timing of these colocalizations in interphase cells. In addition, to our surprise, we found that Aβ immunoreactivities colocalize with the mitotic spindle, a bundle of specialized microtubules. Because of the condensed cytoplasm found in neurons, we suggest that SK-N-SH cells might be a more convenient experimental system for exploring the mechanisms that underlie these protein localizations and the pathology that might result from altered APP protein structure and function.     

Apolipoprotein E affects the amount, form, and anatomical distribution of amyloid β-peptide deposition in homozygous APPV717F transgenic mice

Apolipoprotein E (apoE) has been implicated as a risk factor for Alzheimer’s disease and in the deposition, fibrillogenesis, and clearance of the amyloid β-peptide (Aβ). To examine the in vivo interactions between apoE and Aβ deposition, we examined 12-month-old transgenic (tg) mice expressing human amyloid precursor protein (APP) with the V717F mutation (APP^V717F homozygous) on an APOE null background. Elimination of APOE resulted in a redistribution and alteration in the character of Aβ deposition in homozygous APP^V717F tg mice, with a dramatic reduction in cortical and dentate gyrus deposition, prominent increase in diffuse CA1 and CA3 deposition, and prevention of the formation of thioflavin-S-positive deposits. These alterations in Aβ deposition were not mediated by significant changes in regional APP expression, low-density lipoprotein receptor-related protein expression, or soluble Aβ levels. Thus, apoE in APP^V717F tg mice not only affects the amount and form of Aβ deposition, but also the anatomical distribution of diffuse Aβ deposits. The APP^V717F tg mouse can serve as a model to investigate genetic influences on the vulnerability of specific neuroanatomical regions to Aβ deposition. Received: 11 April 2000 / Revised, accepted: 25 May 2000     

Neprilysin regulates amyloid β peptide levels

That neprilysin (NEP) is a major Aβ peptide-degrading enzyme in vivo is shown by higher Aβ peptide levels in the brain of an NEP knockout mouse. In addition, we show that infusion of an NEP inhibitor, but not inhibitors of other peptidases, into the brains of an APP transgenic mouse elevates Aβ levels. We have investigated the use of NEP as a potential therapeutic agent to prevent the accumulation of Aβ peptides in the brain. Lentivirus expressing NEP was initially used to demonstrate the ability of the enzyme to reduce Aβ levels in a model CHO cell line and to make primary hippocampal neurons resistant to Aβ-mediated neurotoxicity. Injection of NEP-expressing lentivirus, but not inactive NEP-expressing lentivirus, GFP-expressing lentivirus, or vehicle, into the hippocampus of 12–20-mo-old hAPP transgenic mice led to an approx 50% reduction in the number of amyloid plaques. These studies provide the impetus for further investigating of the use of NEP in a gene transfer therapy paradigm to prevent the accumulation of Aβ and prevent or delay the onset of Alzheimer’s disease.     

Novel tricyclic pyrone compounds prevent intracellular APP C99-induced cell death

Alzheimer’s disease (AD) is an age-related neurodegenerative disorder characterized by the progressive and global loss of cognitive functions. Pathological features include a loss of neurons in vulnerable brain regions and the extracellular deposition of abnormal protein aggregates known as amyloid plaques. Amyloid-β protein (Aβ is the major component of amyloid plaques and is derived from a larger transmembrane glycoprotein, termed amyloid β protein precursor (APP), by proteolysis. The AD research has focused on Aβ production and metabolism, its extracellular deposition, and its cellular toxicity. Recent evidence, however, suggests that Aβ as well as the C-terminal fragments (CTF) of APP can accumulate intraneuronally. The neuronal loss and synaptic transmission deficit in AD may therefore depend on intraneuronal accumulation of Aβ/CTF rather than on extracellular plaque formation. Accordingly, we propose that one of the primary targets of therapeutic intervention should be intracellular Aβ/CTF and its toxic cellular effect. We have established a cell-culture model in which the neurons degenerate on induction of endogenous expression of Aβ/CTF of APP. These cultures have been used to test whether tricyclic pyrone (TP) compounds may prevent Aβ/CTF-mediated neuronal death. The results to date have been encouraging. Lead compounds will now be selected for their abilities to ameliorate Aβ/CTF-mediated pathology in transgenic mice. Our hope is that these compounds may eventually prove beneficial for the prevention and treatment of AD.     

The β-secretase, BACE

Evidence suggests that the β-amyloid peptide (Aβ) is central to the pathophysiology of Alzheimer’s disease (AD). Amyloid plaques, primarily composed of Aβ, progressively develop in the brains of AD patients, and mutations in three genes (APP, PS1, and PS2) cause early onset familial AD (FAD) by directly increasing synthesis of the toxic, plaque-promoting Aβ42 peptide. Given the strong association between Aβ and AD, therapeutic strategies to lower the concentration of Aβ in the brain should prove beneficial for the treatment of AD. One such strategy would involve inhibiting the enzymes that generate Aβ. Aβ is a product of catabolism of the large TypeI membrane protein, amyloid precursor protein (APP). Two proteases, called β- and γ-secretase, mediate the endoproteolysis of APP to liberate the Aβ peptide. For over a decade, the molecular identities of these proteases were unknown. Recently, the γ-secretase has been tentatively identified as the presenilin proteins, PS1 and PS2, and the identity of the β-secretase has been shown to be the novel transmembrane aspartic protease, β-site APP cleaving enzyme 1 (BACE1; also called Asp2 and memapsin2). BACE2, a novel protease homologous to BACE1, was also identified, and together the two enzymes define a new family of transmembrane aspartic proteases. BACE1 exhibits all the properties of the β-secretase, and as the key rate-limiting enzyme that initiates the formation of Aβ, BACE1 is an attractive drug target for AD. Here, I review the identification and initial characterization of BACE1 and BACE2, and summarize our current understanding of BACE1 post-translational processing and intracellular trafficking. In addition, I discuss recent studies of BACE1 knockout mice and the BACE1 X-ray structure, and relate implications for BACE1 drug development.     

Detection of amyloid beta aggregates in the brain of BALB/c mice after <Emphasis Type="Italic">Chlamydia pneumoniae</Emphasis> infection

Neuroinflammation, initiated by cerebral infection, is increasingly postulated as an aetiological factor in neurodegenerative diseases such as Alzheimer’s disease (AD). We investigated whether Chlamydia pneumoniae (Cpn) infection results in extracellular aggregation of amyloid beta (Aβ) in BALB/c mice. At 1 week post intranasal infection (p.i.), Cpn DNA was detected predominantly in the olfactory bulbs by PCR, whereas brains at 1 and 3 months p.i. were Cpn negative. At 1 and 3 months p.i., extracellular Aβ immunoreactivity was detected in the brain of Cpn-infected mice but also in the brain of mock-infected mice and mice that were neither Cpn infected nor mock infected. However, these extracellular Aβ aggregates showed morphological differences compared to extracellular Aβ aggregates detected in the brain of transgenic APP751^SL/PS1^M146L mice. These data do not unequivocally support the hypothesis that Cpn infection induces the formation of AD-like Aβ plaques in the brain of BALB/c mice, as suggested before. However, future studies are required to resolve these differences and to investigate whether Cpn is indeed an etiological factor in AD pathogenesis.     

Overexpression of wild-type human APP in mice causes cognitive deficits and pathological features unrelated to Aβ levels

Transgenic mice expressing mutant human amyloid precursor protein (APP) develop an age-dependent amyloid pathology and memory deficits, but no overt neuronal loss. Here, in mice overexpressing wild-type human APP (hAPP_wt) we found an early memory impairment, particularly in the water maze and to a lesser extent in the object recognition task, but β-amyloid peptide (Aβ₄₂) was barely detectable in the hippocampus. In these mice, hAPP processing was basically non-amyloidogenic, with high levels of APP carboxy-terminal fragments, C83 and APP intracellular domain. A tau pathology with an early increase in the levels of phosphorylated tau in the hippocampus, a likely consequence of enhanced ERK1/2 activation, was also observed. Furthermore, these mice presented a loss of synapse-associated proteins: PSD95, AMPA and NMDA receptor subunits and phosphorylated CaMKII. Importantly, signs of neurodegeneration were found in the hippocampal CA1 subfield and in the entorhinal cortex that were associated to a marked loss of MAP2 immunoreactivity. Conversely, in mice expressing mutant hAPP, high levels of Aβ₄₂ were found in the hippocampus, but no signs of neurodegeneration were apparent. The results support the notion of Aβ-independent pathogenic pathways in Alzheimer's disease.