Autosomal‐dominant Alzheimer's disease mutations at the same codon of amyloid precursor protein differentially alter Aβ production

Autosomal‐dominant Alzheimer's disease (ADAD) is a genetic disorder caused by mutations in Amyloid Precursor Protein (APP) or Presenilin (PSEN) genes. Studying the mechanisms underlying these mutations can provide insight into the pathways that lead to AD pathology. The majority of biochemical studies on APP mutations to‐date have focused on comparing mechanisms between mutations at different codons. It has been assumed that amino acid position is a major determinant of protein dysfunction and clinical phenotype. However, the differential effect of mutations at the same codon has not been sufficiently addressed. In the present study we compared the effects of the aggressive ADAD‐associated APP I716F mutation with I716V and I716T on APP processing in human neuroglioma and CHO‐K1 cells. All APP I716 mutations increased the ratio of Aβ42/40 and changed the product line preference of γ‐secretase towards Aβ38 production. In addition, the APP I716F mutation impaired the ε‐cleavage and the fourth cleavage of γ‐secretase and led to abnormal APP β‐CTF accumulation at the plasma membrane. Taken together, these data indicate that APP mutations at the same codon can induce diverse abnormalities in APP processing, some resembling PSEN1 mutations. These differential effects could explain the clinical differences observed among ADAD patients bearing different APP mutations at the same position.

     

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.

     

Aging‐induced Akt activation involves in aging‐related pathologies and Aβ‐induced toxicity

Multicellular signals are altered in the processes of both aging and neurodegenerative diseases, including Alzheimer's disease (AD). Similarities in behavioral and cellular functional changes suggest a common regulator between aging and AD that remains undetermined. Our genetics and behavioral approaches revealed the regulatory role of Akt in both aging and AD pathogenesis. In this study, we found that the activity of Akt is upregulated during aging through epidermal growth factor receptor activation by using the fruit fly as an in vivo model. Downregulation of Akt in neurons improved cell survival, locomotor activity, and starvation challenge in both aged and Aβ42‐expressing flies. Interestingly, increased cAMP levels attenuated both Akt activation‐induced early death and Aβ42‐induced learning deficit in flies. At the molecular level, overexpression of Akt promoted Notch cleavage, suggesting that Akt is an endogenous activity regulator of γ‐secretase. Taken together, this study revealed that Akt is involved in the aging process and Aβ toxicity, and manipulating Akt can restore both neuronal functions and improve behavioral activity during the processes of aging and AD pathogenesis.     

Functional analysis and purification of a Pen‐2 fusion protein for γ‐secretase structural studies

The 19‐transmembrane, multisubunit γ‐secretase complex generates the amyloid β‐peptide (Aβ) of Alzheimer's disease (AD) by an unusual intramembrane proteolysis of the β‐amyloid precursor protein. The complex, which similarly processes many other type 1 transmembrane substrates, is composed of presenilin, Aph1, nicastrin, and presenilin enhancer (Pen‐2), all of which are necessary for proper complex maturation and enzymatic activity. Obtaining a high‐resolution atomic structure of the intact complex would greatly aid the rational design of compounds to modulate activity but is a very difficult task. A complementary method is to generate structures for each individual subunit to allow one to build a model of the entire complex. Here, we describe a method by which recombinant human Pen‐2 can be purified from bacteria to > 95% purity at milligram quantities per liter, utilizing a maltose binding protein tag to both increase solubility and facilitate purification. Expressing the same construct in mammalian cells, we show that the large N‐terminal maltose binding protein tag on Pen‐2 still permits incorporation into the complex and subsequent presenilin‐1 endoproteolysis, nicastrin glycosylation and proteolytic activity. These new methods provide valuable tools to study the structure and function of Pen‐2 and the γ‐secretase complex.

     

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.     

Substrate determinants in the C99 juxtamembrane domains differentially affect γ–secretase cleavage specificity and modulator pharmacology

The molecular mechanisms governing γ‐secretase cleavage specificity are not fully understood. Herein, we demonstrate that extending the transmembrane domain of the amyloid precursor protein‐derived C99 substrate in proximity to the cytosolic face strongly influences γ–secretase cleavage specificity. Sequential insertion of leucines or replacement of membrane‐anchoring lysines by leucines elevated the production of Aβ42, whilst lowering production of Aβ40. A single insertion or replacement was sufficient to produce this phenotype, suggesting that the helical length distal to the ε–site is a critical determinant of γ‐secretase cleavage specificity. Replacing the lysine at the luminal membrane border (K28) with glutamic acid (K28E) increased Aβ37 and reduced Aβ42 production. Maintaining a positive charge with an arginine replacement, however, did not alter cleavage specificity. Using two potent and structurally distinct γ–secretase modulators (GSMs), we elucidated the contribution of K28 to the modulatory mechanism. Surprisingly, whilst lowering the potency of the non‐steroidal anti‐inflammatory drug‐type GSM, the K28E mutation converted a heteroaryl‐type GSM to an inverse GSM. This result implies the proximal lysine is critical for the GSM mechanism and pharmacology. This region is likely a major determinant for substrate binding and we speculate that modulation of substrate binding is the fundamental mechanism by which GSMs exert their action.     

Pre‐synaptic localization of the γ‐secretase‐inhibiting protein p24α2 in the mammalian brain

Dysregulated metabolism and consequent extracellular accumulation of amyloid‐β (Aβ) peptides in the brain underlie the pathogenesis of Alzheimer's disease. Extracellular Aβ in the brain parenchyma is mainly secreted from the pre‐synaptic terminals of neuronal cells in a synaptic activity‐dependent manner. The p24 family member p24α₂ reportedly attenuates Aβ generation by inhibiting γ‐secretase processing of amyloid precursor protein; however, the pattern of expression and localization of p24α₂ in the brain remains unknown. We performed immunohistochemical staining and subcellular fractionation for p24α₂ in the mouse brain. Immunostaining showed that p24α₂ is broadly distributed in the gray matter of the central nervous system and is predominantly localized to synapses. Subcellular fractionation revealed prominent localization of p24α₂ in the pre‐synaptic terminals. Immunoisolation of synaptic vesicles (SV) indicated that p24α₂ is condensed at active zone‐docked SV. During development, p24α₂ expression is highest in the post‐natal period and gradually decreases with age. We also confirmed that amyloid precursor protein and γ‐secretase components are localized at active zone‐docked SV. Our results suggest a novel functional role for p24α₂ in the regulation of synaptic transmission and synaptogenesis, and provide evidence for the participation of p24α₂ in the regulation of Aβ generation and secretion in the brain.

     

Mitochondrial accumulation of APP and Aβ: significance for Alzheimer disease pathogenesis

Accumulating evidence suggest that alterations in energy metabolism are among the earliest events that occur in the Alzheimer disease (AD) affected brain. Energy consumption is drastically decreased in the AD-affected regions of cerebral cortex and hippocampus pointing towards compromised mitochondrial function of neurons within specific brain regions. This is accompanied by an elevated production of reactive oxygen species contributing to increased rates of neuronal loss in the AD-affected brain regions. In this review, we will discuss the role of mitochondrial function and dysfunction in AD. We will focus on the consequences of amyloid precursor protein and amyloid-β peptide accumulation in mitochondria and their involvement in AD pathogenesis.     

Rational design of amyloid β peptide–binding proteins: Pseudo‐Aβ β‐sheet surface presented in green fluorescent protein binds tightly and preferentially to structured Aβ

Some neurodegenerative diseases such as Alzheimer disease (AD) and Parkinson disease are caused by protein misfolding. In AD, amyloid β‐peptide (Aβ) is thought to be a toxic agent by self‐assembling into a variety of aggregates involving soluble oligomeric intermediates and amyloid fibrils. Here, we have designed several green fluorescent protein (GFP) variants that contain pseudo‐Aβ β‐sheet surfaces and evaluated their abilities to bind to Aβ and inhibit Aβ oligomerization. Two GFP variants P13H and AP93Q bound tightly to Aβ, K_d = 260 nM and K_d = 420 nM, respectively. Moreover, P13H and AP93Q were capable of efficiently suppressing the generation of toxic Aβ oligomers as shown by a cell viability assay. By combining the P13H and AP93Q mutations, a super variant SFAB4 comprising four strands of Aβ‐derived sequences was designed and bound more tightly to Aβ (K_d = 100 nM) than those having only two pseudo‐Aβ strands. The SFAB4 protein preferentially recognized the soluble oligomeric intermediates of Aβ more than both unstructured monomer and mature amyloid fibrils. Thus, the design strategy for embedding pseudo‐Aβ β‐sheet structures onto a protein surface arranged in the β‐barrel structure is useful to construct molecules capable of binding tightly to Aβ and inhibiting its aggregation. This strategy may provide implication for the diagnostic and therapeutic development in the treatment of AD. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Comparison of neurotoxicity of different aggregated forms of Aβ40, Aβ42 and Aβ43 in cell cultures

The abnormal deposition of amyloid‐β (Aβ) peptides in the brain is the main neuropathological hallmark of Alzheimer's disease (AD). Amyloid deposits are formed by a heterogeneous mixture of Aβ peptides, among which the most studied are Aβ40 and Aβ42. Aβ40 is abundantly produced in the human brain, but the level of Aβ42 is remarkably increased in the brain of AD patients. Aside from Aβ40 and Aβ42, recent data have raised the possibility that Aβ43 peptides may be instrumental in AD pathogenesis. Besides its length, whether the Aβ aggregated form accounts for the neurotoxicity is also particularly controversial. Aβ fibrils are generally considered as key pathogenic substances in AD pathogenesis. Nevertheless, recent data implicated soluble Aβ oligomers as the main cause of synaptic dysfunction and memory loss in AD. To further address this uncertainty, we analyzed the neurotoxicity of different Aβ species and Aβ forms at the cellular level. The results showed that Aβ42 could form oligomers significantly faster than Aβ40 and Aβ43 and Aβ42 oligomers showed the greatest level of neurotoxicity. Regardless of the length of Aβ peptides, Aβ oligomers induced significantly higher cytotoxicity compared with the other two Aβ forms. Surprisingly, the neurotoxicity of fibrils in PC12 cells was only marginally but not significantly stronger than monomers, contrary to previous reports. Altogether, our findings demonstrate the high pathogenicity of Aβ42 among the three Aβ species and support the idea that Aβ42 oligomers contribute to the pathological events leading to neurodegeneration in AD. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

Neuronal localization of the TNFα converting enzyme (TACE) in brain tissue and its correlation to amyloid plaques

The tumor necrosis factor (TNF)‐α converting enzyme (TACE) can cleave the cell‐surface ectodomain of the amyloid‐β precursor protein (APP), thus decreasing the generation of amyloid‐β (Aβ) by cultured non‐neuronal cells. While the amyloidogenic processing of APP in neurons is linked to the pathogenesis of Alzheimer's disease (AD), the expression of TACE in neurons has not yet been examined. Thus, we assessed TACE expression in a series of neuronal and non‐neuronal cell types by Western blots. We found that TACE was present in neurons and was only faintly detectable in lysates of astrocytes, oligodendrocytes, and microglial cells. Immunohistochemical analysis was used to determine the cellular localization of TACE in the human brain, and its expression was detected in distinct neuronal populations, including pyramidal neurons of the cerebral cortex and granular cell layer neurons in the hippocampus. Very low levels of TACE were seen in the cerebellum, with Purkinje cells at the granular‐molecular boundary staining faintly. Because TACE was localized predominantly in areas of the brain that are affected by amyloid plaques in AD, we examined its expression in a series of AD brains. We found that AD and control brains showed similar levels of TACE staining, as well as similar patterns of TACE expression. By double labeling for Aβ plaques and TACE, we found that TACE‐positive neurons often colocalized with amyloid plaques in AD brains. These observations support a neuronal role for TACE and suggest a mechanism for its involvement in AD pathogenesis as an antagonist of Aβ formation. © 2001 John Wiley & Sons, Inc. J Neurobiol 49: 40–46, 2001     

Brains of rhesus monkeys display Aβ deposits and glial pathology while lacking Aβ dimers and other Alzheimer's pathologies

Cerebral amyloid beta (Aβ) deposits are the main early pathology of Alzheimer's disease (AD). However, abundant Aβ deposits also occur spontaneously in the brains of many healthy people who are free of AD with advancing aging. A crucial unanswered question in AD prevention is why AD does not develop in some elderly people, despite the presence of Aβ deposits. The answer may lie in the composition of Aβ oligomer isoforms in the Aβ deposits of healthy brains, which are different from AD brains. However, which Aβ oligomer triggers the transformation from aging to AD pathogenesis is still under debate. Some researchers insist that the Aβ 12‐mer causes AD pathology, while others suggest that the Aβ dimer is the crucial molecule in AD pathology. Aged rhesus monkeys spontaneously develop Aβ deposits in the brain with striking similarities to those of aged humans. Thus, rhesus monkeys are an ideal natural model to study the composition of Aβ oligomer isoforms and their downstream effects on AD pathology. In this study, we found that Aβ deposits in aged monkey brains included 3‐mer, 5‐mer, 9‐mer, 10‐mer, and 12‐mer oligomers, but not 2‐mer oligomers. The Aβ deposits, which were devoid of Aβ dimers, induced glial pathology (microgliosis, abnormal microglia morphology, and astrocytosis), but not the subsequent downstream pathologies of AD, including Tau pathology, neurodegeneration, and synapse loss. Our results indicate that the Aβ dimer plays an important role in AD pathogenesis. Thus, targeting the Aβ dimer is a promising strategy for preventing AD.     

Intracellular Itinerary of Internalised β‐Secretase,BACE1, and Its Potential Impact on β‐Amyloid Peptide Biogenesis

β‐Secretase (BACE1) cleavage of the amyloid precursor protein (APP) represents the initial step in the formation of the Alzheimer's disease associated amyloidogenic Aβ peptide. Substantive evidence indicates that APP processing by BACE1 is dependent on intracellular sorting of this enzyme. Nonetheless, knowledge of the intracellular trafficking pathway of internalised BACE1 remains in doubt. Here we show that cell surface BACE1 is rapidly internalised by the AP2/clathrin dependent pathway in transfected cells and traffics to early endosomes and Rab11‐positive, juxtanuclear recycling endosomes, with very little transported to the TGN as has been previously suggested. Moreover, BACE1 is predominantly localised to the early and recycling endosome compartments in different cell types, including neuronal cells. In contrast, the majority of internalised wild‐type APP traffics to late endosomes/lysosomes. To explore the relevance of the itinerary of BACE1 on APP processing, we generated a BACE1 chimera containing the cytoplasmic tail of TGN38 (BACE/TGN38), which cycles between the cell surface and TGN in an AP2‐dependent manner. Wild‐type BACE1 is less efficient in Aβ production than the BACE/TGN38 chimera, highlighting the relevance of the itinerary of BACE1 on APP processing. Overall the data suggests that internalised BACE1 and APP diverge at early endosomes and that Aβ biogenesis is regulated in part by the recycling itinerary of BACE1.     

Calpain cleavage and inactivation of the sodium calcium exchanger‐3 occur downstream of Aβ in Alzheimer's disease

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by pathological deposits of β‐amyloid (Aβ) in senile plaques, intracellular neurofibrillary tangles (NFTs) comprising hyperphosphorylated aggregated tau, synaptic dysfunction and neuronal death. Substantial evidence indicates that disrupted neuronal calcium homeostasis is an early event in AD that could mediate synaptic dysfunction and neuronal toxicity. Sodium calcium exchangers (NCXs) play important roles in regulating intracellular calcium, and accumulating data suggests that reduced NCX function, following aberrant proteolytic cleavage of these exchangers, may contribute to neurodegeneration. Here, we show that elevated calpain, but not caspase‐3, activity is a prominent feature of AD brain. In addition, we observe increased calpain‐mediated cleavage of NCX3, but not a related family member NCX1, in AD brain relative to unaffected tissue and that from other neurodegenerative conditions. Moreover, the extent of NCX3 proteolysis correlated significantly with amounts of Aβ1–42. We also show that exposure of primary cortical neurons to oligomeric Aβ1–42 results in calpain‐dependent cleavage of NCX3, and we demonstrate that loss of NCX3 function is associated with Aβ toxicity. Our findings suggest that Aβ mediates calpain cleavage of NCX3 in AD brain and therefore that reduced NCX3 activity could contribute to the sustained increases in intraneuronal calcium concentrations that are associated with synaptic and neuronal dysfunction in AD.     

In AβPP‐overexpressing cultured human muscle fibers proteasome inhibition enhances phosphorylation of AβPP751 and GSK3β activation: effects mitigated by lithium and apparently relevant to sporadic inclusion‐body myositis

Muscle fiber degeneration in sporadic inclusion‐body myositis (s‐IBM) is characterized by accumulation of multiprotein aggregates, including aggregated amyloid‐β (Aβ)‐precursor protein 751 (AβPP751), Aβ, phosphorylated tau, and other ‘Alzheimer‐characteristic’ proteins. Proteasome inhibition is an important component of the s‐IBM pathogenesis. In brains of Alzheimer’s disease (AD) patients and AD transgenic‐mouse models, phosphorylation of neuronal AβPP695 (p‐AβPP) on Thr668 (equivalent to T724 of AβPP751) is considered detrimental because it increases generation of cytotoxic Aβ and induces tau phosphorylation. Activated glycogen synthase kinase3β (GSK3β) is involved in phosphorylation of both AβPP and tau. Lithium, an inhibitor of GSK3β, was reported to reduce levels of both the total AβPP and p‐AβPP in AD animal models. In relation to s‐IBM, we now show for the first time that (1) In AβPP‐overexpressing cultured human muscle fibers (human muscle culture IBM model: (a) proteasome inhibition significantly increases GSK3β activity and AβPP phosphorylation, (b) treatment with lithium decreases (i) phosphorylated‐AβPP, (ii) total amount of AβPP, (iii) Aβ oligomers, and (iv) GSK3β activity; and (c) lithium improves proteasome function. (2) In biopsied s‐IBM muscle fibers, GSK3β is significantly activated and AβPP is phosphorylated on Thr724. Accordingly, treatment with lithium, or other GSK3β inhibitors, might benefit s‐IBM patients.     

Spectroscopic detection of β ‐sheet structure in nascent Aβ oligomers

Deep‐UV resonance Raman (UVRR) spectroscopy and circular dichroism (CD) were employed to study the secondary structure of Aβ(1–42) in fresh samples with increasing fractions of oligomeric peptide. A feature with a minimum at ～217 nm appeared in CD spectra of samples containing oligomeric Aβ(1–42). UVRR spectra more closely resembled those of disordered proteins. The primary difference between UVRR spectra was the ratio of the 1236 cm^–1 to 1260 cm^–1 amide III peak intensities, which shifted in favor of the 1236 cm^–1 band as the fraction of oligomeric peptide increased. (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Human cerebral vascular amyloid contains both antiparallel and parallel in-register Aβ40 fibrils

The accumulation of fibrillar amyloid-β (Aβ) peptides alongside or within the cerebral vasculature is the hallmark of cerebral amyloid angiopathy (CAA). This condition commonly co-occurs with Alzheimer''s disease (AD) and leads to cerebral microbleeds, intracranial hemorrhages, and stroke. CAA also occurs sporadically in an age-dependent fashion and can be accelerated by the presence of familial Aβ mutant peptides. Recent studies using Fourier transform infrared (FTIR) spectroscopy of vascular Aβ fibrils derived from rodents containing the double E22Q/D23N mutations indicated the presence of a novel antiparallel β-sheet structure. To address whether this structure is associated solely with the familial mutations or is a common feature of CAA, we propagated Aβ fibrils from human brain vascular tissue of patients diagnosed with nonfamilial CAA. Aβ fibrils were isolated from cerebral blood vessels using laser capture microdissection in which specific amyloid deposits were removed from thin slices of the brain tissue. Transmission electron microscopy revealed that these deposits were organized into a tight meshwork of fibrils, which FTIR measurements showed could serve as seeds to propagate the growth of Aβ40 fibrils for structural studies. Solid-state NMR measurements of the fibrils propagated from vascular amyloid showed they contained a mixture of parallel, in-register, and antiparallel β-sheet structures. The presence of fibrils with antiparallel structure derived from vascular amyloid is distinct from the typical parallel, in-register β-sheet structure that appears in fibrils derived from parenchymal amyloid in AD. These observations reveal that different microenvironments influence the structures of Aβ fibrils in the human brain.     

Activation of PKA/SIRT1 signaling pathway by photobiomodulation therapy reduces Aβ levels in Alzheimer's disease models

A hallmark of Alzheimer's disease (AD) is the accumulation of amyloid‐β (Aβ), which correlates significantly with progressive cognitive deficits. Although photobiomodulation therapy (PBMT), as a novel noninvasive physiotherapy strategy, has been proposed to improve neuronal survival, decrease neuron loss, ameliorate dendritic atrophy, and provide overall AD improvement, it remains unknown whether and how this neuroprotective process affects Aβ levels. Here, we report that PBMT reduced Aβ production and plaque formation by shifting amyloid precursor protein (APP) processing toward the nonamyloidogenic pathway, thereby improving memory and cognitive ability in a mouse model of AD. More importantly, a pivotal protein, SIRT1, was involved in this process by specifically up‐regulating ADAM10 and down‐regulating BACE1, which is dependent on the cAMP/PKA pathway in APP/PS1 primary neurons and SH‐SY5Y cells stably expressing human APP Swedish mutation (APPswe). We further found that the activity of the mitochondrial photoacceptor cytochrome c oxidase (CcO) was responsible for PBMT‐induced activation of PKA and SIRT1. Together, our research suggests that PBMT as a viable therapeutic strategy has great potential value in improving cognitive ability and combatting AD.