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2,030 result(s) for "Amyloid Precursor Protein Secretases - metabolism"
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The BACE‐1 inhibitor CNP520 for prevention trials in Alzheimer's disease
The beta‐site amyloid precursor protein cleaving enzyme‐1 (BACE‐1) initiates the generation of amyloid‐β (Aβ), and the amyloid cascade leading to amyloid plaque deposition, neurodegeneration, and dementia in Alzheimer's disease (AD). Clinical failures of anti‐Aβ therapies in dementia stages suggest that treatment has to start in the early, asymptomatic disease states. The BACE‐1 inhibitor CNP520 has a selectivity, pharmacodynamics, and distribution profile suitable for AD prevention studies. CNP520 reduced brain and cerebrospinal fluid (CSF) Aβ in rats and dogs, and Aβ plaque deposition in APP‐transgenic mice. Animal toxicology studies of CNP520 demonstrated sufficient safety margins, with no signs of hair depigmentation, retina degeneration, liver toxicity, or cardiovascular effects. In healthy adults ≥ 60 years old, treatment with CNP520 was safe and well tolerated and resulted in robust and dose‐dependent Aβ reduction in the cerebrospinal fluid. Thus, long‐term, pivotal studies with CNP520 have been initiated in the Generation Program. Synopsis Alzheimer's disease (AD) is a chronic neurodegenerative disorder with increasing incidence in the aging societies, but without any disease‐modifying treatment. Deposition of toxic forms of the protein Aβ in the brain is pathologic. Treatment with a BACE‐1 inhibitor may prevent Aβ deposition. Recent BACE inhibitor clinical trials in patients at early or mild‐to‐moderate disease stage have failed, indicating that treatment needs to start earlier, before the onset of clinical symptoms. BACE inhibitor CNP520 was designed to meet the requirements of prevention treatment. CNP520 in preclinical models showed acute and chronic Aβ reduction, and a favorable safety profile. CNP520 is safe and well tolerated in humans, and dose‐dependently reduced Aβ in cerebrospinal fluid. Prevention studies Generation I and II are underway in patients at enhanced risk to develop symptoms of AD. Graphical Abstract Alzheimer's disease (AD) is a chronic neurodegenerative disorder with increasing incidence in the aging societies, but without any disease‐modifying treatment. Deposition of toxic forms of the protein Aβ in the brain is pathologic. Treatment with a BACE‐1 inhibitor may prevent Aβ deposition.
Identification of disulfiram as a secretase-modulating compound with beneficial effects on Alzheimer’s disease hallmarks
ADAM10 is a metalloproteinase acting on the amyloid precursor protein (APP) as an alpha-secretase in neurons. Its enzymatic activity results in secretion of a neuroprotective APP cleavage product (sAPP-alpha) and prevents formation of the amyloidogenic A-beta peptides, major hallmarks of Alzheimer’s disease (AD). Elevated ADAM10 levels appeared to contribute to attenuation of A-beta-plaque formation and learning and memory deficits in AD mouse models. Therefore, it has been assumed that ADAM10 might represent a valuable target in AD therapy. Here we screened a FDA-approved drug library and identified disulfiram as a novel ADAM10 gene expression enhancer. Disulfiram increased ADAM10 production as well as sAPP-alpha in SH-SY5Y human neuronal cells and additionally prevented A-beta aggregation in an in vitro assay in a dose-dependent fashion. In addition, acute disulfiram treatment of Alzheimer model mice induced ADAM10 expression in peripheral blood cells, reduced plaque-burden in the dentate gyrus and ameliorated behavioral deficits. Alcohol-dependent patients are subjected to disulfiram-treatment to discourage alcohol-consumption. In such patients, enhancement of ADAM10 by disulfiram-treatment was demonstrated in peripheral blood cells. Our data suggest that disulfiram could be repurposed as an ADAM10 enhancer and AD therapeutic. However, efficacy and safety has to be analyzed in Alzheimer patients in the future.
Seizure protein 6 and its homolog seizure 6-like protein are physiological substrates of BACE1 in neurons
Background The protease BACE1 (beta-site APP cleaving enzyme) is a major drug target in Alzheimer’s disease. However, BACE1 therapeutic inhibition may cause unwanted adverse effects due to its additional functions in the nervous system, such as in myelination and neuronal connectivity. Additionally, recent proteomic studies investigating BACE1 inhibition in cell lines and cultured murine neurons identified a wider range of neuronal membrane proteins as potential BACE1 substrates, including seizure protein 6 (SEZ6) and its homolog SEZ6L. Methods and results We generated antibodies against SEZ6 and SEZ6L and validated these proteins as BACE1 substrates in vitro and in vivo. Levels of the soluble, BACE1-cleaved ectodomain of both proteins (sSEZ6, sSEZ6L) were strongly reduced upon BACE1 inhibition in primary neurons and also in vivo in brains of BACE1-deficient mice. BACE1 inhibition increased neuronal surface levels of SEZ6 and SEZ6L as shown by cell surface biotinylation, demonstrating that BACE1 controls surface expression of both proteins. Moreover, mass spectrometric analysis revealed that the BACE1 cleavage site in SEZ6 is located in close proximity to the membrane, similar to the corresponding cleavage site in SEZ6L. Finally, an improved method was developed for the proteomic analysis of murine cerebrospinal fluid (CSF) and was applied to CSF from BACE-deficient mice. Hereby, SEZ6 and SEZ6L were validated as BACE1 substrates in vivo by strongly reduced levels in the CSF of BACE1-deficient mice. Conclusions This study demonstrates that SEZ6 and SEZ6L are physiological BACE1 substrates in the murine brain and suggests that sSEZ6 and sSEZ6L levels in CSF are suitable markers to monitor BACE1 inhibition in mice.
Efficacy and safety of tarenflurbil in mild to moderate Alzheimer's disease: a randomised phase II trial
The amyloid-β peptide Aβ 42 has been implicated in the pathogenesis of Alzheimer's disease (AD). We aimed to test the effects of tarenflurbil, a selective Aβ 42-lowering agent (SALA), on cognition and function in patients with mild to moderate AD. 210 patients living in the community who had a mini-mental state examination (MMSE) score of 15–26 were randomly assigned to receive tarenflurbil twice per day (400 mg [n=69] or 800 mg [n=70]) or placebo (n=71) for 12 months in a phase II, multicentre, double-blind study. Primary efficacy outcomes were the AD assessment scale cognitive subscale (ADAS-cog), the Alzheimer's Disease Cooperative Study activities of daily living scale (ADCS-ADL), and the clinical dementia rating sum of boxes (CDR-sb). In a 12-month extended treatment phase, patients who had received tarenflurbil continued to receive the same dose, and patients who had received placebo were randomly assigned to tarenflurbil at 800 mg or 400 mg twice per day. Primary efficacy analyses were done by intention to treat. This trial is registered with Health Canada (084527) and the Medicines and Healthcare products Regulatory Agency in the UK (20365/0001/A 69316). A prespecified interaction analysis revealed that patients with mild AD (baseline MMSE 20–26) and moderate AD (baseline MMSE 15–19) responded differently to tarenflurbil in the ADAS-cog and the ADCS-ADL (p≥0·10); therefore, these groups were analysed separately. Patients with mild AD in the 800 mg tarenflurbil group had lower rates of decline than did those in the placebo group in activities of daily living (ADCS-ADL difference in slope 3·98 [95% CI 0·33 to 7·62] points per year, effect size [reduction from placebo decline rate] 46·4%, Cohen's d 0·45; p=0·033) and global function (CDR-sb difference −0·80 [−1·57 to −0·03] points per year, effect size 35·7%, Cohen's d 0·42; p=0·042); slowing of cognitive decline did not differ significantly (ADAS-cog difference −1·36 [−4·07 to 1·36] points per year, effect size 33·7%, Cohen's d 0·20; p=0·327). In patients with moderate AD, 800 mg tarenflurbil twice per day had no significant effects on ADCS-ADL and ADAS-cog and had a negative effect on CDR-sb (−52%, Cohen's d −1·08; p=0·003). The most common adverse events were diarrhoea (in seven, nine, and five patients in the 800 mg, 400 mg, and placebo groups, respectively), nausea (in seven, seven, and four patients), and dizziness (in five, nine, and four patients). Patients with mild AD who were in the 800 mg tarenflurbil group for 24 months had lower rates of decline for all three primary outcomes than did patients who were in the placebo group for months 0–12 and a tarenflurbil group for months 12–24 (all p<0·001), and had better outcomes than did patients who were in the placebo group for months 0–12 and the 800 mg tarenflurbil group for months 12–24 (all p<0·05). 800 mg tarenflurbil twice per day was well tolerated for up to 24 months of treatment, with evidence of a dose-related effect on measures of daily activities and global function in patients with mild AD. Myriad Pharmaceuticals.
Basic Science and Pathogenesis
Alzheimer's disease (AD), an untreatable synaptic disorder, is the most frequent cause of dementia. It is still unclear which mechanisms drive the early synapse dysfunction in the most common late-onset AD (LOAD). The second most important LOAD risk gene identified, BIN1, is an endocytic regulator. We implicated Bin1 in BACE1 recycling with Bin1 loss of function, increasing axonal beta-amyloid42. Since endocytic trafficking is essential for synapse function, we hypothesize that Bin1 may regulate synaptic endocytic trafficking, which may be disrupted by Bin1's loss of function or beta-amyloid42. We aim to dissect Bin1 causal mechanisms of synaptic dysfunction to assess how the risk for LOAD increases. Synaptically mature mouse primary cortical neurons and brain hippocampus were used to investigate Bin1 synaptic endocytic localization with immunofluorescence and synaptosomes. Using knockdown, overexpression, and rescue approaches the impact on synaptic endosome size and synaptic density was determined using super-resolution fluorescence microscopy and quantitative subcellular image analysis. Bin1 was enriched in synaptic vesicle brain fractions, supporting its presynaptic function. Unexpectedly, Bin1 is enriched proximal synapses, identified as inhibitory GABAergic presynaptic terminals in primary neurons and the brain. Notably, Bin1 down-regulation specifically reduced inhibitory synapse density and increased neuronal excitability. Bin1 loss increased inhibitory synaptic vesicle release and endocytosis, exhausting presynaptic endosomes. Interestingly, the impact on inhibitory synapses is independent of beta-amyloid production. Moreover, Bin1 LOAD mutations interfere with Bin1 function and are likely to cause loss of function. Bin1 is an inhibitory presynaptic protein. The LOAD mutations may cause Bin1 loss of function, affecting inhibitory synapses. Losing inhibitory transmission may turn excitatory neurons hyperactive, accelerating the loss of excitatory synapses. In the future, we aim to dissect the underlying mechanisms by which Bin1 mutations interfere with Bin1's role in synaptic vesicle mechanisms at inhibitory presynaptic terminals.
Casein Kinase 2 dependent phosphorylation of eIF4B regulates BACE1 expression in Alzheimer’s disease
Alzheimer’s disease (AD) is the most common age-related neurodegenerative disorder. Increased Aβ production plays a fundamental role in the pathogenesis of the disease and BACE1, the protease that triggers the amyloidogenic processing of APP, is a key protein and a pharmacological target in AD. Changes in neuronal activity have been linked to BACE1 expression and Aβ generation, but the underlying mechanisms are still unclear. We provide clear evidence for the role of Casein Kinase 2 in the control of activity-driven BACE1 expression in cultured primary neurons, organotypic brain slices, and murine AD models. More specifically, we demonstrate that neuronal activity promotes Casein Kinase 2 dependent phosphorylation of the translation initiation factor eIF4B and this, in turn, controls BACE1 expression and APP processing. Finally, we show that eIF4B expression and phosphorylation are increased in the brain of APPPS1 and APP-KI mice, as well as in AD patients. Overall, we provide a definition of a mechanism linking brain activity with amyloid production and deposition, opening new perspectives from the therapeutic standpoint.
η-Secretase processing of APP inhibits neuronal activity in the hippocampus
A new pathway for the processing of β-amyloid precursor protein (APP) is described in which η-secretase activity, in part mediated by the MT5-MMP metalloproteinase, cleaves APP, and further processing by ADAM10 and BACE1 generates proteolytic fragments capable of inhibiting long-term potentiation in the hippocampus. Neuronal inhibition by APP by-products Michael Willem et al . describe a previously unknown pathway for the processing of β-amyloid precursor protein (APP) in which η-secretase cleaves APP to yield a soluble C-terminal fragment termed CTF-η. The soluble fragment, sAPP-η can be further processed by ADAM10 and BACE1 to generate the peptides Aη-α and Aη-β respectively, which are capable of inhibiting long-term potentiation in the hippocampus. The relevant η-secretase activity is largely due to the membrane-bound matrix metalloproteinase, MT5-MMP, whose activity is enriched in dystrophic neurites in a mouse model of Alzheimer's disease and in the brains of Alzheimer's patients. Genetic or pharmacological inhibition of BACE1 results in increased accumulation of both CTF-η and Aη-α. This work suggests that BACE 1-based therapies may result in the generation of another potentially toxic substance (Aη-α) and that therapeutic inhibition of BACE1 activity requires careful titration. Alzheimer disease (AD) is characterized by the accumulation of amyloid plaques, which are predominantly composed of amyloid-β peptide 1 . Two principal physiological pathways either prevent or promote amyloid-β generation from its precursor, β-amyloid precursor protein (APP), in a competitive manner 1 . Although APP processing has been studied in great detail, unknown proteolytic events seem to hinder stoichiometric analyses of APP metabolism in vivo 2 . Here we describe a new physiological APP processing pathway, which generates proteolytic fragments capable of inhibiting neuronal activity within the hippocampus. We identify higher molecular mass carboxy-terminal fragments (CTFs) of APP, termed CTF-η, in addition to the long-known CTF-α and CTF-β fragments generated by the α- and β-secretases ADAM10 (a disintegrin and metalloproteinase 10) and BACE1 (β-site APP cleaving enzyme 1), respectively. CTF-η generation is mediated in part by membrane-bound matrix metalloproteinases such as MT5-MMP, referred to as η-secretase activity. η-Secretase cleavage occurs primarily at amino acids 504–505 of APP 695 , releasing a truncated ectodomain. After shedding of this ectodomain, CTF-η is further processed by ADAM10 and BACE1 to release long and short Aη peptides (termed Aη-α and Aη-β). CTFs produced by η-secretase are enriched in dystrophic neurites in an AD mouse model and in human AD brains. Genetic and pharmacological inhibition of BACE1 activity results in robust accumulation of CTF-η and Aη-α. In mice treated with a potent BACE1 inhibitor, hippocampal long-term potentiation was reduced. Notably, when recombinant or synthetic Aη-α was applied on hippocampal slices ex vivo , long-term potentiation was lowered. Furthermore, in vivo single-cell two-photon calcium imaging showed that hippocampal neuronal activity was attenuated by Aη-α. These findings not only demonstrate a major functionally relevant APP processing pathway, but may also indicate potential translational relevance for therapeutic strategies targeting APP processing.
Regulation of beta-amyloid production in neurons by astrocyte-derived cholesterol
Alzheimer’s disease (AD) is characterized by the presence of amyloid β (Aβ) plaques, tau tangles, inflammation, and loss of cognitive function. Genetic variation in a cholesterol transport protein, apolipoprotein E (apoE), is the most common genetic risk factor for sporadic AD. In vitro evidence suggests that apoE links to Aβ production through nanoscale lipid compartments (lipid clusters), but its regulation in vivo is unclear. Here, we use superresolution imaging in the mouse brain to show that apoE utilizes astrocyte-derived cholesterol to specifically traffic neuronal amyloid precursor protein (APP) in and out of lipid clusters, where it interacts with β- and γ-secretases to generate Aβ-peptide. We find that the targeted deletion of astrocyte cholesterol synthesis robustly reduces amyloid and tau burden in a mouse model of AD. Treatment with cholesterol-free apoE or knockdown of cholesterol synthesis in astrocytes decreases cholesterol levels in cultured neurons and causes APP to traffic out of lipid clusters, where it interacts with α-secretase and gives rise to soluble APP-α (sAPP-α), a neuronal protective product of APP. Changes in cellular cholesterol have no effect on α-, β-, and γ-secretase trafficking, suggesting that the ratio of Aβ to sAPP-α is regulated by the trafficking of the substrate, not the enzymes.We conclude that cholesterol is kept low in neurons, which inhibits Aβ accumulation and enables the astrocyte regulation of Aβ accumulation by cholesterol signaling.
The innate immunity protein IFITM3 modulates γ-secretase in Alzheimer’s disease
Innate immunity is associated with Alzheimer’s disease 1 , but the influence of immune activation on the production of amyloid-β is unknown 2 , 3 . Here we identify interferon-induced transmembrane protein 3 (IFITM3) as a γ-secretase modulatory protein, and establish a mechanism by which inflammation affects the generation of amyloid-β. Inflammatory cytokines induce the expression of IFITM3 in neurons and astrocytes, which binds to γ-secretase and upregulates its activity, thereby increasing the production of amyloid-β. The expression of IFITM3 is increased with ageing and in mouse models that express familial Alzheimer’s disease genes. Furthermore, knockout of IFITM3 reduces γ-secretase activity and the formation of amyloid plaques in a transgenic mouse model (5xFAD) of early amyloid deposition. IFITM3 protein is upregulated in tissue samples from a subset of patients with late-onset Alzheimer’s disease that exhibit higher γ-secretase activity. The amount of IFITM3 in the γ-secretase complex has a strong and positive correlation with γ-secretase activity in samples from patients with late-onset Alzheimer’s disease. These findings reveal a mechanism in which γ-secretase is modulated by neuroinflammation via IFITM3 and the risk of Alzheimer’s disease is thereby increased. The IFITM3 innate immunity protein directly binds presenilin near the active site and upregulates γ-secretase activity and the production of amyloid-β, and IFITM3 is upregulated in patients with late-onset Alzheimer’s disease.
Accumulation of amyloid precursor protein C-terminal fragments triggers mitochondrial structure, function, and mitophagy defects in Alzheimer’s disease models and human brains
Several lines of recent evidence indicate that the amyloid precursor protein-derived C-terminal fragments (APP-CTFs) could correspond to an etiological trigger of Alzheimer’s disease (AD) pathology. Altered mitochondrial homeostasis is considered an early event in AD development. However, the specific contribution of APP-CTFs to mitochondrial structure, function, and mitophagy defects remains to be established. Here, we demonstrate in neuroblastoma SH-SY5Y cells expressing either APP Swedish mutations, or the β-secretase-derived APP-CTF fragment (C99) combined with β- and γ-secretase inhibition, that APP-CTFs accumulation independently of Aβ triggers excessive mitochondrial morphology alteration (i.e., size alteration and cristae disorganization) associated with enhanced mitochondrial reactive oxygen species production. APP-CTFs accumulation also elicit basal mitophagy failure illustrated by enhanced conversion of LC3, accumulation of LC3-I and/or LC3-II, non-degradation of SQSTM1/p62, inconsistent Parkin and PINK1 recruitment to mitochondria, enhanced levels of membrane and matrix mitochondrial proteins, and deficient fusion of mitochondria with lysosomes. We confirm the contribution of APP-CTFs accumulation to morphological mitochondria alteration and impaired basal mitophagy in vivo in young 3xTgAD transgenic mice treated with γ-secretase inhibitor as well as in adeno-associated-virus-C99 injected mice. Comparison of aged 2xTgAD and 3xTgAD mice indicates that, besides APP-CTFs, an additional contribution of Aβ to late-stage mitophagy activation occurs. Importantly, we report on mitochondrial accumulation of APP-CTFs in human post-mortem sporadic AD brains correlating with mitophagy failure molecular signature. Since defective mitochondria homeostasis plays a pivotal role in AD pathogenesis, targeting mitochondrial dysfunctions and/or mitophagy by counteracting early APP-CTFs accumulation may represent relevant therapeutic interventions in AD.