A synthetic peptide corresponding to a region of the human pericentriolar material 1 (PCM‐1) protein binds β‐amyloid (Aβ1‐42) oligomers

We have recently reported that a ~19‐kDa polypeptide, rPK‐4, is a protein kinase Cs inhibitor that is 89% homologous to the 1171–1323 amino acid region of the 228‐kDa human pericentriolar material‐1 (PCM‐1) protein (Chakravarthy et al. 2012). We have now discovered that rPK‐4 binds oligomeric amyloid‐β peptide (Aβ)_1‐42 with high affinity. Most importantly, a PCM‐1‐selective antibody co‐precipitated Aβ and amyloid β precursor protein (AβPP) from cerebral cortices and hippocampi from AD (Alzheimer's disease) transgenic mice that produce human AβPP and Aβ_1‐42, suggesting that PCM‐1 may interact with amyloid precursor protein/Aβ in vivo. We have identified rPK‐4′s Aβ‐binding domain using a set of overlapping synthetic peptides. We have found with ELISA, dot‐blot, and polyacrylamide gel electrophoresis techniques that a ~ 5 kDa synthetic peptide, amyloid binding peptide (ABP)‐p4‐5 binds Aβ_1‐42 at nM levels. Most importantly, ABP‐p4‐5, like rPK‐4, appears to preferentially bind Aβ_1‐42 oligomers, believed to be the toxic AD‐drivers. As expected from these observations, ABP‐p4‐5 prevented Aβ_1‐42 from killing human SH‐SY5Y neuroblastoma cells via apoptosis. These findings indicate that ABP‐p4‐5 is a possible candidate therapeutic for AD.     

Differential physiologic responses of α7 nicotinic acetylcholine receptors to β‐amyloid1–40 and β‐amyloid1–42

The β‐amyloid peptides (Aβ), Aβ_1–40 and Aβ_1–42, have been implicated in Alzheimer's disease (AD) pathology. Although Aβ_1–42 is generally considered to be the pathological peptide in AD, both Aβ_1–40 and Aβ_1–42 have been used in a variety of experimental models without discrimination. Here we show that monomeric or oligomeric forms of the two Aβ peptides, when interact with the neuronal cation channel, α7 nicotinic acetylcholine receptors (α7nAChR), would result in distinct physiologic responses as measured by acetylcholine release and calcium influx experiments. While Aβ_1–42 effectively attenuated these α7nAChR‐dependent physiology to an extent that was apparently irreversible, Aβ_1–40 showed a lower inhibitory activity that could be restored upon washings with physiologic buffers or treatment with α7nAChR antagonists. Our data suggest a clear pharmacological distinction between Aβ_1–40 and Aβ_1–42. © 2003 Wiley Periodicals, Inc. J Neurobiol 55: 25–30, 2003     

Rationally designed dehydroalanine (ΔAla)‐containing peptides inhibit amyloid‐β (Aβ) peptide aggregation

Among the pathological hallmarks of Alzheimer's disease (AD) is the deposition of amyloid‐β (Aβ) peptides, primarily Aβ (1–40) and Aβ (1–42), in the brain as senile plaques. A large body of evidence suggests that cognitive decline and dementia in AD patients arise from the formation of various aggregated forms of Aβ, including oligomers, protofibrils and fibrils. Hence, there is increasing interest in designing molecular agents that can impede the aggregation process and that can lead to the development of therapeutically viable compounds. Here, we demonstrate the ability of the specifically designed α,β‐dehydroalanine (ΔAla)‐containing peptides P1 (K‐L‐V‐F‐ΔA‐I‐ΔA) and P2 (K‐F‐ΔA‐ΔA‐ΔA‐F) to inhibit Aβ (1–42) aggregation. The mechanism of interaction of the two peptides with Aβ (1–42) seemed to be different and distinct. Overall, the data reveal a novel application of ΔAla‐containing peptides as tools to disrupt Aβ aggregation that may lead to the development of anti‐amyloid therapies not only for AD but also for many other protein misfolding diseases. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 456–465, 2009. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Wnt signaling loss accelerates the appearance of neuropathological hallmarks of Alzheimer's disease in J20‐APP transgenic and wild‐type mice

Alzheimer's disease (AD ) is a neurodegenerative pathology characterized by aggregates of amyloid‐β (Aβ) and phosphorylated tau protein, synaptic dysfunction, and spatial memory impairment. The Wnt signaling pathway has several key functions in the adult brain and has been associated with AD , mainly as a neuroprotective factor against Aβ toxicity and tau phosphorylation. However, dysfunction of Wnt/β‐catenin signaling might also play a role in the onset and development of the disease. J20 APP swInd transgenic (Tg) mouse model of AD was treated i.p. with various Wnt signaling inhibitors for 10 weeks during pre‐symptomatic stages. Then, cognitive, biochemical and histochemical analyses were performed. Wnt signaling inhibitors induced severe changes in the hippocampus, including alterations in Wnt pathway components and loss of Wnt signaling function, severe cognitive deficits, increased tau phosphorylation and Aβ_1–42 peptide levels, decreased Aβ42/Aβ40 ratio and Aβ_1–42 concentration in the cerebral spinal fluid, and high levels of soluble Aβ species and synaptotoxic oligomers in the hippocampus, together with changes in the amount and size of senile plaques. More important, we also observed severe alterations in treated wild‐type (WT ) mice, including behavioral impairment, tau phosphorylation, increased Aβ_1–42 in the hippocampus, decreased Aβ_1–42 in the cerebral spinal fluid, and hippocampal dysfunction. Wnt inhibition accelerated the development of the pathology in a Tg AD mouse model and contributed to the development of Alzheimer's‐like changes in WT mice. These results indicate that Wnt signaling plays important roles in the structure and function of the adult hippocampus and suggest that inhibition of the Wnt signaling pathway is an important factor in the pathogenesis of AD .

Read the Editorial Highlight for this article on page 356 .

     

Mitofusin‐2 knockdown increases ER–mitochondria contact and decreases amyloid β‐peptide production

Mitochondria are physically and biochemically in contact with other organelles including the endoplasmic reticulum (ER). Such contacts are formed between mitochondria‐associated ER membranes (MAM), specialized subregions of ER, and the outer mitochondrial membrane (OMM). We have previously shown increased expression of MAM‐associated proteins and enhanced ER to mitochondria Ca²⁺ transfer from ER to mitochondria in Alzheimer's disease (AD) and amyloid β‐peptide (Aβ)‐related neuronal models. Here, we report that siRNA knockdown of mitofusin‐2 (Mfn2), a protein that is involved in the tethering of ER and mitochondria, leads to increased contact between the two organelles. Cells depleted in Mfn2 showed increased Ca²⁺ transfer from ER to mitchondria and longer stretches of ER forming contacts with OMM. Interestingly, increased contact resulted in decreased concentrations of intra‐ and extracellular Aβ₄₀ and Aβ₄₂. Analysis of γ‐secretase protein expression, maturation and activity revealed that the low Aβ concentrations were a result of impaired γ‐secretase complex function. Amyloid‐β precursor protein (APP), β‐site APP‐cleaving enzyme 1 and neprilysin expression as well as neprilysin activity were not affected by Mfn2 siRNA treatment. In summary, our data shows that modulation of ER–mitochondria contact affects γ‐secretase activity and Aβ generation. Increased ER–mitochondria contact results in lower γ‐secretase activity suggesting a new mechanism by which Aβ generation can be controlled.     

The stress response neuropeptide CRF increases amyloid‐β production by regulating γ‐secretase activity

The biological underpinnings linking stress to Alzheimer's disease (AD) risk are poorly understood. We investigated how corticotrophin releasing factor (CRF), a critical stress response mediator, influences amyloid‐β (Aβ) production. In cells, CRF treatment increases Aβ production and triggers CRF receptor 1 (CRFR1) and γ‐secretase internalization. Co‐immunoprecipitation studies establish that γ‐secretase associates with CRFR1; this is mediated by β‐arrestin binding motifs. Additionally, CRFR1 and γ‐secretase co‐localize in lipid raft fractions, with increased γ‐secretase accumulation upon CRF treatment. CRF treatment also increases γ‐secretase activity in vitro, revealing a second, receptor‐independent mechanism of action. CRF is the first endogenous neuropeptide that can be shown to directly modulate γ‐secretase activity. Unexpectedly, CRFR1 antagonists also increased Aβ. These data collectively link CRF to increased Aβ through γ‐secretase and provide mechanistic insight into how stress may increase AD risk. They also suggest that direct targeting of CRF might be necessary to effectively modulate this pathway for therapeutic benefit in AD, as CRFR1 antagonists increase Aβ and in some cases preferentially increase Aβ42 via complex effects on γ‐secretase.     

Prostaglandin I2 upregulates the expression of anterior pharynx‐defective‐1α and anterior pharynx‐defective‐1β in amyloid precursor protein/presenilin 1 transgenic mice

Cyclooxygenase‐2 (COX‐2) has been recently identified to be involved in the pathogenesis of Alzheimer's disease (AD). Yet, the role of an important COX‐2 metabolic product, prostaglandin (PG) I₂, in the pathogenesis of AD remains unknown. Using human‐ and mouse‐derived neuronal cells as well as amyloid precursor protein/presenilin 1 (APP/PS1) transgenic mice as model systems, we elucidated the mechanism of anterior pharynx‐defective (APH)‐1α and pharynx‐defective‐1β induction. In particular, we found that PGI₂ production increased during the course of AD development. Then, PGI₂ accumulation in neuronal cells activates PKA/CREB and JNK/c‐Jun signaling pathways by phosphorylation, which results in APH‐1α/1β expression. As PGI₂ is an important metabolic by‐product of COX‐2, its suppression by NS398 treatment decreases the expression of APH‐1α/1β in neuronal cells and APP/PS1 mice. More importantly, β‐amyloid protein (Aβ) oligomers in the cerebrospinal fluid (CSF) of APP/PS1 mice are critical for stimulating the expression of APH‐1α/1β, which was blocked by NS398 incubation. Finally, the induction of APH‐1α/1β was confirmed in the brains of patients with AD. Thus, these findings not only provide novel insights into the mechanism of PGI₂‐induced AD progression but also are instrumental for improving clinical therapies to combat AD.     

Mitochondria-specific accumulation of amyloid β induces mitochondrial dysfunction leading to apoptotic cell death

Mitochondria are best known as the essential intracellular organelles that host the homeostasis required for cellular survival, but they also have relevance in diverse disease-related conditions, including Alzheimer's disease (AD). Amyloid β (Aβ) peptide is the key molecule in AD pathogenesis, and has been highlighted in the implication of mitochondrial abnormality during the disease progress. Neuronal exposure to Aβ impairs mitochondrial dynamics and function. Furthermore, mitochondrial Aβ accumulation has been detected in the AD brain. However, the underlying mechanism of how Aβ affects mitochondrial function remains uncertain, and it is questionable whether mitochondrial Aβ accumulation followed by mitochondrial dysfunction leads directly to neuronal toxicity. This study demonstrated that an exogenous Aβ(1-42) treatment, when applied to the hippocampal cell line of mice (specifically HT22 cells), caused a deleterious alteration in mitochondria in both morphology and function. A clathrin-mediated endocytosis blocker rescued the exogenous Aβ(1-42)-mediated mitochondrial dysfunction. Furthermore, the mitochondria-targeted accumulation of Aβ(1-42) in HT22 cells using Aβ(1-42) with a mitochondria-targeting sequence induced the identical morphological alteration of mitochondria as that observed in the APP/PS AD mouse model and exogenous Aβ(1-42)-treated HT22 cells. In addition, subsequent mitochondrial dysfunctions were demonstrated in the mitochondria-specific Aβ(1-42) accumulation model, which proved indistinguishable from the mitochondrial impairment induced by exogenous Aβ(1-42)-treated HT22 cells. Finally, cellular toxicity was directly induced by mitochondria-targeted Aβ(1-42) accumulation, which mimics the apoptosis process in exogenous Aβ(1-42)-treated HT22 cells. Taken together, these results indicate that mitochondria-targeted Aβ(1-42) accumulation is the necessary and sufficient condition for Aβ-mediated mitochondria impairments, and leads directly to cellular death rather than along with other Aβ-mediated signaling alterations.     

Amyloid beta1–42 (Aβ42) up‐regulates the expression of sortilin via the p75NTR/RhoA signaling pathway

Sortilin, a Golgi sorting protein and a member of the VPS10P family, is the co‐receptor for proneurotrophins, regulates protein trafficking, targets proteins to lysosomes, and regulates low density lipoprotein metabolism. The aim of this study was to investigate the expression and regulation of sortilin in Alzheimer's disease (AD). A significantly increased level of sortilin was found in human AD brain and in the brains of 6‐month‐old swedish‐amyloid precursor protein/PS1dE9 transgenic mice. Aβ₄₂ enhanced the protein and mRNA expression levels of sortilin in a dose‐ and time‐dependent manner in SH‐SY5Y cells, but had no effect on sorLA. In addition, proBDNF also significantly increased the protein and mRNA expression of sortilin in these cells. The recombinant extracellular domain of p75^NTR (P75ECD‐FC), or the antibody against the extracellular domain of p75^NTR, blocked the up‐regulation of sortilin induced by Amyloid‐β protein (Aβ), suggesting that Aβ₄₂ increased the expression level of sortilin and mRNA in SH‐SY5Y via the p75^NTR receptor. Inhibition of ROCK, but not Jun N‐terminal kinase, suppressed constitutive and Aβ₄₂‐induced expression of sortilin. In conclusion, this study shows that sortilin expression is increased in the AD brain in human and mice and that Aβ₄₂ oligomer increases sortilin gene and protein expression through p75^NTR and RhoA signaling pathways, suggesting a potential physiological interaction of Aβ₄₂ and sortilin in Alzheimer's disease.

     

A mutation protective against Alzheimer's disease renders amyloid β precursor protein incapable of mediating neurotoxicity

Expression of a familial Alzheimer's disease (AD)‐linked mutant of amyloid β precursor protein (APP) or the binding of transforming growth factor β2 to wild‐type (wt)‐APP causes neuronal death by activating an intracellular death signal (a APP‐mediated intracellular death signal) in the absence of the involvement of amyloid β (Aβ) toxicity in vitro. These neuronal death models may therefore be regarded as Aβ‐independent neuronal death models related to AD. A recent study has shown that the A673T mutation in the APP isoform APP₇₇₀, corresponding to the A598T mutation in the most prevalent neuronal APP isoform APP₆₉₅ (an AD‐protective mutant of APP), is linked to a reduction in the incidence rate of AD. Consistent with this, cells expressing the AD‐protective mutant of APP produce less Aβ than cells expressing wt‐APP. In this study, transforming growth factor β2 caused death in cultured neuronal cells expressing wt‐APP, but not in those expressing the AD‐protective mutant of APP. This result suggests that the AD‐protective mutation of APP reduces the incidence rate of AD by attenuating the APP‐mediated intracellular death signal. In addition, a mutation that causes hereditary cerebral hemorrhage with amyloidosis‐Dutch type also attenuated the APP‐mediated intracellular death signal.

     

Identification of new Presenilin‐1 phosphosites: implication for γ‐secretase activity and Aβ production

An important pathological hallmark of Alzheimer's disease (AD) is the deposition of amyloid‐beta (Aβ) peptides in the brain parenchyma, leading to neuronal death and impaired learning and memory. The protease γ‐secretase is responsible for the intramembrane proteolysis of the amyloid‐β precursor protein (APP), which leads to the production of the toxic Aβ peptides. Thus, an attractive therapeutic strategy to treat AD is the modulation of the γ‐secretase activity, to reduce Aβ42 production. Because phosphorylation of proteins is a post‐translational modification known to modulate the activity of many different enzymes, we used electrospray (LC‐MS/MS) mass spectrometry to identify new phosphosites on highly purified human γ‐secretase. We identified 11 new single or double phosphosites in two well‐defined domains of Presenilin‐1 (PS1), the catalytic subunit of the γ‐secretase complex. Next, mutagenesis and biochemical approaches were used to investigate the role of each phosphosite in the maturation and activity of γ‐secretase. Together, our results suggest that the newly identified phosphorylation sites in PS1 do not modulate γ‐secretase activity and the production of the Alzheimer's Aβ peptides. Individual PS1 phosphosites shall probably not be considered therapeutic targets for reducing cerebral Aβ plaque formation in AD.

     

Fibrillar β‐amyloid 1‐42 alters cytokine secretion,cholinergic signalling and neuronal differentiation

Adult neurogenesis is impaired by inflammatory processes, which are linked to altered cholinergic signalling and cognitive decline in Alzheimer's disease. In this study, we investigated how amyloid beta (Aβ)‐evoked inflammatory responses affect the generation of new neurons from human embryonic stem (hES) cells and the role of cholinergic signalling in regulating this process. The hES were cultured as neurospheres and exposed to fibrillar and oligomeric Aβ_1‐42 (Aβf, AβO) or to conditioned medium from human primary microglia activated with either Aβ_1‐42 or lipopolysaccharide. The neurospheres were differentiated for 29 days in vitro and the resulting neuronal or glial phenotypes were thereafter assessed. Secretion of cytokines and the enzymes acetylcholinesterase (AChE), butyrylcholinesterase (BuChE) and choline acetyltransferase (ChAT) involved in cholinergic signalling was measured in medium throughout the differentiation. We report that differentiating neurospheres released various cytokines, and exposure to Aβf, but not AβO, increased the secretion of IL‐6, IL‐1β and IL‐2. Aβf also influenced the levels of AChE, BuChE and ChAT in favour of a low level of acetylcholine. These changes were linked to an altered secretion pattern of cytokines. A different pattern was observed in microglia activated by Aβf, demonstrating decreased secretion of TNF‐α, IL‐1β and IL‐2 relative to untreated cells. Subsequent exposure of differentiating neurospheres to Aβf or to microglia‐conditioned medium decreased neuronal differentiation and increased glial differentiation. We suggest that a basal physiological secretion of cytokines is involved in shaping the differentiation of neurospheres and that Aβf decreases neurogenesis by promoting a microenvironment favouring hypo‐cholinergic signalling and gliogenesis.     

Oral Presentations OP01: Neurodegenerative Diseases. BCL‐W Plays a key neuroprotective role in Alzheimer's disease

The mechanisms underlying neuronal degeneration in Alzheimer's disease (AD) are very controversial and none more so than whether apoptosis plays a role. Although neurons in AD face a wide assortment of apoptogenic stimuli, the temporal dichotomy between the acuteness of apoptosis vs. the chronicity of AD suggests that apoptosis should be extremely rare in AD. In this regard, survival factor(s) must be involved. In this study, we investigated Bcl‐w, a pro‐survival member of the Bcl‐2 family. Although expressed at low levels in brains of control cases, Bcl‐w is significantly up‐regulated in AD as shown by both immunocytochemistry and immunoblot analysis. Astonishingly, increased Bcl‐w was found to be associated with neurofibrillary pathologies in AD, which was further demonstrated by an EM study. Since neuronal death in AD is thought to be triggered by increased production of amyloid‐β (Aβ), it was interesting to find that exposure of human M17 neuroblastoma cells to Aβ1–42 (1 nm ?10 μm ) dramatically up‐regulates Bcl‐w protein levels. Such increases may be a protective response that attenuates apoptotic processes. Consistent with this, transfected M17 cells overexpressing Bcl‐w were protected from both STS‐induced and Aβ‐induced apoptosis compared to vector‐transfected controls. Notably, both tau phosphorylation and p38 is inhibited in Bcl‐w transfected cells which may contribute to the neuroprotective role of Bcl‐w. Taken together, these set of in vitro and in vivo results suggest that Bcl‐w plays an important protective role in neurons in the AD brain.     

Aromatic‐interaction‐mediated inhibition of β‐amyloid assembly structures and cytotoxicity

Abnormal aggregation of β‐amyloid (Aβ) peptide plays an important role in the onset and progress of Alzheimer's disease (AD); hence, targeting Aβ aggregation is considered as an effective therapeutic strategy. Here, we studied the aromatic‐interaction‐mediated inhibitory effect of oligomeric polypeptides (K8Y8, K4Y8, K8W8) on Aβ42 fibrillization process. The polypeptides containing lysine as well as representative aromatic amino acids of tryptophan or tyrosine were found to greatly suppress the aggregation as evaluated by thioflavin T assay. Circular dichroism spectra showed that the β‐sheet formation of Aβ42 peptides decreased with the polypeptide additives. Molecular docking studies revealed that the oligomeric polypeptides could preferentially bind to Aβ42 through π–π stacking between aromatic amino acids and Phe19, together with hydrogen bonding. The cell viability assay confirmed that the toxicity of Aβ42 to SH‐SY5Y cells was markedly reduced in the presence of polypeptides. This study could be beneficial for developing peptide‐based inhibitory agents for amyloidoses. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

New mechanism of nerve injury in Alzheimer’s disease: β‐amyloid‐induced neuronal pyroptosis

The present study was designed to investigate the role of β‐amyloid (Aβ_1‐42) in inducing neuronal pyroptosis and its mechanism. Mice cortical neurons (MCNs) were used in this study, LPS + Nigericin was used to induce pyroptosis in MCNs (positive control group), and Aβ_1‐42 was used to interfere with MCNs. In addition, propidium iodide (PI) staining was used to examine cell permeability, lactate dehydrogenase (LDH) release assay was employed to detect cytotoxicity, immunofluorescence (IF) staining was used to investigate the expression level of the key protein GSDMD, Western blot was performed to detect the expression levels of key proteins, and enzyme‐linked immunosorbent assay (ELISA) was utilized to determine the expression levels of inflammatory factors in culture medium, including IL‐1β, IL‐18 and TNF‐α. Small interfering RNA (siRNA) was used to silence the mRNA expression of caspase‐1 and GSDMD, and Aβ_1‐42 was used to induce pyroptosis, followed by investigation of the role of caspase‐1‐mediated GSDMD cleavage in pyroptosis. In addition, necrosulfonamide (NSA), an inhibitor of GSDMD oligomerization, was used for pre‐treatment, and Aβ_1‐42 was subsequently used to observe the pyroptosis in MCNs. Finally, AAV9‐siRNA‐caspase‐1 was injected into the tail vein of APP/PS1 double transgenic mice (Alzheimer's disease mice) for caspase‐1 mRNA inhibition, followed by observation of behavioural changes in mice and measurement of the expression of inflammatory factors and pyroptosis‐related protein. As results, Aβ_1‐42 could induce pyroptosis in MCNs, increase cell permeability and enhance LDH release, which were similar to the LPS + Nigericin‐induced pyroptosis. Meanwhile, the expression levels of cellular GSDMD and p30‐GSDMD were up‐regulated, the levels of NLRP3 inflammasome and GSDMD‐cleaved protein caspase‐1 were up‐regulated, and the levels of inflammatory factors in the medium were also up‐regulated. siRNA intervention in caspase‐1 or GSDMD inhibited Aβ_1‐42‐induced pyroptosis, and NSA pre‐treatment also caused the similar inhibitory effects. The behavioural ability of Alzheimer's disease (AD) mice was relieved after the injection of AAV9‐siRNA‐caspase‐1, and the expression of pyroptosis‐related protein in the cortex and hippocampus was down‐regulated. In conclusion, Aβ_1‐42 could induce pyroptosis by GSDMD protein, and NLRP3‐caspase‐1 signalling was an important signal to mediate GSDMD cleavage, which plays an important role in Aβ_1‐42‐induced pyroptosis in neurons. Therefore, GSDMD is expected to be a novel therapeutic target for AD.     

Retracted: S14G‐humanin inhibits Aβ1–42 fibril formation,disaggregates preformed fibrils,and protects against Aβ‐induced cytotoxicity in vitro

The aggregation of soluble amyloid‐beta (Aβ) peptide into oligomers/fibrils is one of the key pathological features in Alzheimer's disease (AD). The Aβ aggregates are considered to play a pivotal role in the pathogenesis of AD. Therefore, inhibiting Aβ aggregation and destabilizing preformed Aβ fibrils would be an attractive therapeutic target for prevention and treatment of AD. S14G‐humanin (HNG), a synthetic derivative of Humanin (HN), has been shown to be a strong neuroprotective agent against various AD‐related insults. Recent studies have shown that HNG can significantly improve cognitive deficits and reduce insoluble Aβ levels as well as amyloid plaque burden without affecting amyloid precursor protein processing and Aβ production in transgenic AD models. However, the potential mechanisms by which HNG reduces Aβ‐related pathology in vivo remain obscure. In the present study, we found that HNG could significantly inhibit monomeric Aβ1–42 aggregation into fibrils and destabilize preformed Aβ1–42 fibrils in a concentration‐dependent manner by Thioflavin T fluorescence assay. In transmission electron microscope study, we observed that HNG was effective in inhibiting Aβ1–42 fibril formation and disrupting preformed Aβ1–42 fibrils, exhibiting various types of amorphous aggregates without identifiable Aβ fibrils. Furthermore, HNG‐treated monomeric or fibrillar Aβ1–42 was found to significantly reduce Aβ1–42‐mediated cytotoxic effects on PC12 cells in a dose‐dependent manner by MTT assay. Collectively, our results demonstrate for the first time that HNG not only inhibits Aβ1–42 fibril formation but also disaggregates preformed Aβ1–42 fibrils, which provides the novel evidence that HNG may have anti‐Aβ aggregation and fibrillogenesis, and fibril‐destabilizing properties. Together with previous studies, we concluded that HNG may have promising therapeutic potential as a multitarget agent for the prevention and/or treatment of AD. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Hopeahainol A attenuates memory deficits by targeting β‐amyloid in APP/PS1 transgenic mice

Increasing evidence demonstrates that amyloid beta (Aβ) elicits mitochondrial dysfunction and oxidative stress, which contributes to the pathogenesis of Alzheimer's disease (AD). Identification of the molecules targeting Aβ is thus of particular significance in the treatment of AD. Hopeahainol A (HopA), a polyphenol with a novel skeleton obtained from Hopea hainanensis, is potentially acetylcholinesterase‐inhibitory and anti‐oxidative in H₂O₂‐treated PC12 cells. In this study, we reported that HopA might bind to Aβ_1–42 directly and inhibit the Aβ_1–42 aggregation using a combination of molecular dynamics simulation, binding assay, transmission electron microscopic analysis and staining technique. We also demonstrated that HopA decreased the interaction between Aβ_1–42 and Aβ‐binding alcohol dehydrogenase, which in turn reduced mitochondrial dysfunction and oxidative stress in vivo and in vitro. In addition, HopA was able to rescue the long‐term potentiation induction by protecting synaptic function and attenuate memory deficits in APP/PS1 mice. Our data suggest that HopA might be a promising drug for therapeutic intervention in AD.     

Aβ1–42 oligomer‐induced leakage in an in vitro blood–brain barrier model is associated with up‐regulation of RAGE and metalloproteinases,and down‐regulation of tight junction scaffold proteins

Accumulating evidence indicates that abnormal deposition of amyloid‐β (Aβ) peptide in the brain is responsible for endothelial cell damage and consequently leads to blood–brain barrier (BBB) leakage. However, the mechanisms underlying BBB disruption are not well described. We employed an monolayer BBB model comprising bEnd.3 cell and found that BBB leakage was induced by treatment with Aβ_1–42, and the levels of tight junction (TJ) scaffold proteins (ZO‐1, Claudin‐5, and Occludin) were decreased. Through comparisons of the effects of the different components of Aβ_1–42, including monomer (Aβ_1–42‐Mono), oligomer (Aβ_1–42‐Oligo), and fibril (Aβ_1–42‐Fibril), our data confirmed that Aβ_1–42‐Oligo is likely to be the most important damage factor that results in TJ damage and BBB leakage in Alzheimer's disease. We found that the incubation of bEnd.3 cells with Aβ_1–42 significantly up‐regulated the level of receptor for advanced glycation end‐products (RAGE). Co‐incubation of a polyclonal antibody to RAGE and Aβ_1–42‐Oligo in bEnd.3 cells blocked RAGE suppression of Aβ_1–42‐Oligo‐induced alterations in TJ scaffold proteins and reversed Aβ_1–42‐Oligo‐induced up‐regulation of RAGE, matrix metalloproteinase (MMP)‐2, and MMP‐9. Furthermore, we found that these effects induced by Aβ_1–42‐Oligo treatment were effectively suppressed by knockdown of RAGE using small interfering RNA (siRNA) transfection. We also found that GM 6001, a broad‐spectrum MMP inhibitor, partially reversed the Aβ_1–42‐Oligo‐induced inhibitor effects in bEnd.3 cells. Thus, these results suggested that RAGE played an important role in Aβ‐induced BBB leakage and alterations of TJ scaffold proteins, through a mechanism that involved up‐regulation of MMP‐2 and MMP‐9.

     

Posttranslational modification impact on the mechanism by which amyloid‐β induces synaptic dysfunction

Oligomeric amyloid‐β (Aβ) 1‐42 disrupts synaptic function at an early stage of Alzheimer's disease (AD). Multiple posttranslational modifications of Aβ have been identified, among which N‐terminally truncated forms are the most abundant. It is not clear, however, whether modified species can induce synaptic dysfunction on their own and how altered biochemical properties can contribute to the synaptotoxic mechanisms. Here, we show that a prominent isoform, pyroglutamated Aβ3(pE)‐42, induces synaptic dysfunction to a similar extent like Aβ1‐42 but by clearly different mechanisms. In contrast to Aβ1‐42, Aβ3(pE)‐42 does not directly associate with synaptic membranes or the prion protein but is instead taken up by astrocytes and potently induces glial release of the proinflammatory cytokine TNFα. Moreover, Aβ3(pE)‐42‐induced synaptic dysfunction is not related to NMDAR signalling and Aβ3(pE)‐42‐induced impairment of synaptic plasticity cannot be rescued by D1‐agonists. Collectively, the data point to a scenario where neuroinflammatory processes together with direct synaptotoxic effects are caused by posttranslational modification of soluble oligomeric Aβ and contribute synergistically to the onset of synaptic dysfunction in AD.