Mutant Amyloid Precursor Protein Research Articles

Detection of sex-specific glutamate changes in subregions of hippocampus in an early-stage Alzheimer's disease mouse model using GluCEST MRI.

Regional glucose hypometabolism resulting in glutamate loss has been shown as one of the characteristics of Alzheimer's disease (AD). Because the impact of AD varies between the sexes, we utilized glutamate-weighted chemical exchange saturation transfer (GluCEST) magnetic resonance imaging (MRI) for high-resolution spatial mapping of cerebral glutamate and investigated subregional changes in a sex-specific manner. Eight-month-old male and female AD mice harboring mutant amyloid precursor protein (APPNL-F/NL-F: n = 36) and wild-type (WT: n = 39) mice underwent GluCEST MRI, followed by proton magnetic resonance spectroscopy (1H-MRS) in hippocampus and thalamus/hypothalamus using 9.4T preclinical MR scanner. GluCEST measurements revealed significant (p≤0.02) glutamate loss in the entorhinal cortex (% change ± standard error: 8.73±2.12%), hippocampus (11.29±2.41%), and hippocampal fimbriae (19.15±2.95%) of male AD mice. A similar loss of hippocampal glutamate in male AD mice (11.22±2.33%; p = 0.01) was also observed in 1H-MRS. GluCEST MRI detected glutamate reductions in the fimbria and entorhinal cortex of male AD mice, which was not reported previously. Resilience in female AD mice against these changes indicates an intact status of cerebral energy metabolism. Glutamate levels were monitored in different brain regions of early-stage Alzheimer's disease (AD) and wild-type male and female mice using glutamate-weighted chemical exchange saturation transfer (GluCEST) magnetic resonance imaging (MRI). Male AD mice exhibited significant glutamate loss in the hippocampus, entorhinal cortex, and the fimbriae of the hippocampus. Interestingly, female AD mice did not have any glutamate loss in any brain region and should be investigated further to find the probable cause. These findings demonstrate previously unreported sex-specific glutamate changes in hippocampal sub-regions using high-resolution GluCEST MRI.

Alzheimer-mutant γ-secretase complexes stall amyloid β-peptide production.

Missense mutations in the amyloid precursor protein (APP) and presenilin-1 (PSEN1) cause early-onset familial Alzheimer's disease (FAD) and alter proteolytic production of secreted 38-to-43-residue amyloid β-peptides (Aβ) by the PSEN1-containing γ-secretase complex, ostensibly supporting the amyloid hypothesis of pathogenesis. However, proteolysis of APP substrate by γ-secretase is processive, involving initial endoproteolysis to produce long Aβ peptides of 48 or 49 residues followed by carboxypeptidase trimming in mostly tripeptide increments. We recently reported evidence that FAD mutations in APP and PSEN1 cause deficiencies in early steps in processive proteolysis of APP substrate C99 and that this results from stalled γ-secretase enzyme-substrate and/or enzyme-intermediate complexes. These stalled complexes triggered synaptic degeneration in a C. elegans model of FAD independently of Aβ production. Here we conducted full quantitative analysis of all proteolytic events on APP substrate by γ-secretase with six additional PSEN1 FAD mutations and found that all six are deficient in multiple processing steps. However, only one of these (F386S) was deficient in certain trimming steps but not in endoproteolysis. Fluorescence lifetime imaging microscopy in intact cells revealed that all six PSEN1 FAD mutations lead to stalled γ-secretase enzyme-substrate/intermediate complexes. The F386S mutation, however, does so only in Aβ-rich regions of the cells, not in C99-rich regions, consistent with the deficiencies of this mutant enzyme only in trimming of Aβ intermediates. These findings provide further evidence that FAD mutations lead stalled and stabilized γ-secretase enzyme-substrate and/or enzyme-intermediate complexes and are consistent with the stalled process rather than the products of γ-secretase proteolysis as the pathogenic trigger.

Biological function of Aβ peptides revealed by analysis of membrane-association properties: Implications for Azheimer's disease pathogenesis

Proteolytic processing of amyloid precursor protein (APP) plays a critical role in the pathogenesis of Azheimer's disease (AD). Sequential cleavage of APP by β and γ secretases leads to generation of Aβ40 (non-amyloidogenic) and Aβ42 (amyloidogenic) peptides. Despite intense studies, the biological function of these peptides and the mechanism of Aβ42 toxicity is poorly understood. In the previous publications we proposed that association of Aβ peptides with the endosomal membranes may have important implications for pathogenesis of AD (Kim and Bezprozvanny, IJMS, 2021, vol 22, 13600; Kim and Bezprozvanny, IJMS, 2023, vol 24, 2092). To understand potential biological importance of such interaction, we focused on the region of Aβ peptides involved in peri-membrane association (E682 to N698). We discovered that association of this region with the membranes is reminiscent of several known anti-microbial peptides (AMP) such as PA13, Aurein1.2 and BP100. Our analysis further revealed that energy of peri-membrane association of Aβ40 is significantly weaker than for Aβ42 or AMP peptides, but it can be increased in the presence of non-amyloidogenic FAD mutations or in the presence of cholesterol in the membrane. Based on similarity with established mechanism of action of AMP peptides, we propose that Aβ peptides affect the curvature of endosomal membranes and shift the balance between endosomal recycling to plasma membrane and late endosomal/lysosomal pathway. We further propose that these effects are enhanced as a result of non-amyloidogenic FAD mutations in the sequence of Aβ peptides or in the presence of cholesterol in the membrane. The proposed model provides potential mechanistic explanation to synaptic defects induced by increased levels of Aβ42, by non-amyloidogenic FAD mutations in APP and by age-related increase in the levels of cholesterol in the brain.

Neocortical cholinergic pathology after neonatal brain injury is increased by Alzheimer's disease-related genes in mice

Hypoxic-ischemic encephalopathy (HIE) in neonates causes mortality and neurologic morbidity, including poor cognition with a complex neuropathology. Injury to the cholinergic basal forebrain and its rich innervation of cerebral cortex may also drive cognitive pathology. It is uncertain whether genes associated with adult cognition-related neurodegeneration worsen outcomes after neonatal HIE. We hypothesized that neocortical damage caused by neonatal HI in mice is ushered by persistent cholinergic innervation and interneuron (IN) pathology that correlates with cognitive outcome and is exacerbated by genes linked to Alzheimer's disease. We subjected non-transgenic (nTg) C57Bl6 mice and mice transgenically (Tg) expressing human mutant amyloid precursor protein (APP-Swedish variant) and mutant presenilin (PS1-ΔE9) to the Rice-Vannucci HI model on postnatal day 10 (P10). nTg and Tg mice with sham procedure were controls. Visual discrimination (VD) was tested for cognition. Cortical and hippocampal cholinergic axonal and IN pathology and Aβ plaques, identified by immunohistochemistry for choline acetyltransferase (ChAT) and 6E10 antibody respectively, were counted at P210. Simple ChAT+ axonal swellings were present in all sham and HI groups; Tg mice had more than their nTg counterparts, but HI did not affect the number of axonal swellings in APP/PS1 Tg mice. In contrast, complex ChAT+ neuritic clusters (NC) occurred only in Tg mice; HI increased that burden. The abundance of ChAT+ clusters in specific regions correlated with decreased VD. The frequency of attritional ChAT+ INs in the entorhinal cortex (EC) was increased in Tg shams relative to their nTg counterparts, but HI obviated this difference. Cholinergic IN pathology in EC correlated with NC number. The Aβ deposition in APP/PS1 Tg mice was not exacerbated by HI, nor did it correlate with other metrics. Adult APP/PS1 Tg mice have significant cortical cholinergic axon and EC ChAT+ IN pathologies; some pathology was exacerbated by neonatal HI and correlated with VD. Mechanisms of neonatal HI induced cognitive deficits and cortical neuropathology may be modulated by genetic risk, perhaps accounting for some of the variability in outcomes.

The cellular adaptor GULP1 interacts with ATG14 to potentiate autophagy and APP processing

Autophagy is a highly conserved catabolic mechanism by which unnecessary or dysfunctional cellular components are removed. The dysregulation of autophagy has been implicated in various neurodegenerative diseases, including Alzheimer’s disease (AD). Understanding the molecular mechanism(s)/molecules that influence autophagy may provide important insights into developing therapeutic strategies against AD and other neurodegenerative disorders. Engulfment adaptor phosphotyrosine-binding domain-containing protein 1 (GULP1) is an adaptor that interacts with amyloid precursor protein (APP) to promote amyloid-β peptide production via an unidentified mechanism. Emerging evidence suggests that GULP1 has a role in autophagy. Here, we show that GULP1 is involved in autophagy through an interaction with autophagy-related 14 (ATG14), which is a regulator of autophagosome formation. GULP1 potentiated the stimulatory effect of ATG14 on autophagy by modulating class III phosphatidylinositol 3-kinase complex 1 (PI3KC3-C1) activity. The effect of GULP1 is attenuated by a GULP1 mutation (GULP1m) that disrupts the GULP1–ATG14 interaction. Conversely, PI3KC3-C1 activity is enhanced in cells expressing APP but not in those expressing an APP mutant that does not bind GULP1, which suggests a role of GULP1–APP in regulating PI3KC3-C1 activity. Notably, GULP1 facilitates the targeting of ATG14 to the endoplasmic reticulum (ER). Moreover, the levels of both ATG14 and APP are elevated in the autophagic vacuoles (AVs) of cells expressing GULP1, but not in those expressing GULP1m. APP processing is markedly enhanced in cells co-expressing GULP1 and ATG14. Hence, GULP1 alters APP processing by promoting the entry of APP into AVs. In summary, we unveil a novel role of GULP1 in enhancing the targeting of ATG14 to the ER to stimulate autophagy and, consequently, APP processing.

Eta-secretase-like processing of the amyloid precursor protein (APP) by the rhomboid protease RHBDL4

The amyloid precursor protein (APP) is a key protein in Alzheimer’s disease synthesized in the endoplasmic reticulum (ER) and translocated to the plasma membrane where it undergoes proteolytic cleavages by several proteases. Conversely to other known proteases, we previously elucidated rhomboid protease RHBDL4 as a novel APP processing enzyme where several cleavages likely occur already in the ER. Interestingly, the pattern of RHBDL4-derived large APP C-terminal fragments resemble those generated by the η-secretase or MT5-MMP, which was described to generate so called Aη fragments. The similarity in large APP C-terminal fragments between both proteases raised the question whether RHBDL4 may contribute to η-secretase activity and Aη-like fragments. Here, we identified two cleavage sites of RHBDL4 in APP by mass spectrometry, which, intriguingly, lie in close proximity to the MT5-MMP cleavage sites. Indeed, we observed that RHBDL4 generates Aη-like fragments in vitro without contributions of α-, β-, or γ-secretases. Such Aη-like fragments are likely generated in the ER since RHBDL4-derived APP-C-terminal fragments do not reach the cell surface. Inherited, familial APP mutations appear to not affect this processing pathway. In RHBDL4 knockout mice, we observed increased cerebral full length APP in comparison to wild type (WT) in support of RHBDL4 being a physiologically relevant protease for APP. Furthermore, we found secreted Aη fragments in dissociated mixed cortical cultures from WT mice, however significantly less Aη fragments in RHBDL4 knockout cultures. Our data underscores that RHBDL4 contributes to η-secretease-like processing of APP and that RHBDL4 is a physiologically relevant protease for APP.

Bradykinin promotes immune responses in differentiated embryonic neurospheres carrying APPswe and PS1dE9 mutations

BackgroundNeural progenitor cells (NPCs) can be cultivated from developing brains, reproducing many of the processes that occur during neural development. They can be isolated from a variety of animal models, such as transgenic mice carrying mutations in amyloid precursor protein (APP) and presenilin 1 and 2 (PSEN 1 and 2), characteristic of familial Alzheimer’s disease (fAD). Modulating the development of these cells with inflammation-related peptides, such as bradykinin (BK) and its antagonist HOE-140, enables the understanding of the impact of such molecules in a relevant AD model.ResultsWe performed a global gene expression analysis on transgenic neurospheres treated with BK and HOE-140. To validate the microarray data, quantitative real-time reverse-transcription polymerase chain reaction (RT-PCR) was performed on 8 important genes related to the immune response in AD such as CCL12, CCL5, CCL3, C3, CX3CR1, TLR2 and TNF alpha and Iba-1. Furthermore, comparative analysis of the transcriptional profiles was performed between treatments, including gene ontology and reactome enrichment, construction and analysis of protein-protein interaction networks and, finally, comparison of our data with human dataset from AD patients. The treatments affected the expression levels of genes mainly related to microglia-mediated neuroinflammatory responses, with BK promoting an increase in the expression of genes that enrich processes, biological pathways, and cellular components related to immune dysfunction, neurodegeneration and cell cycle. B2 receptor inhibition by HOE-140 resulted in the reduction of AD-related anomalies caused in this system.ConclusionsBK is an important immunomodulatory agent and enhances the immunological changes identified in transgenic neurospheres carrying the genetic load of AD. Bradykinin treatments modulate the expression rates of genes related to microglia-mediated neuroinflammation. Inhibiting bradykinin activity in Alzheimer’s disease may slow disease progression.

Transmissible long-term neuroprotective and pro-cognitive effects of 1-42 beta-amyloid with A2T icelandic mutation in an Alzheimer's disease mouse model.

The amyloid cascade hypothesis assumes that the development of Alzheimer's disease (AD) is driven by a self-perpetuating cycle, in which β-amyloid (Aβ) accumulation leads to Tau pathology and neuronal damages. A particular mutation (A673T) of the amyloid precursor protein (APP) was identified among Icelandic population. It provides a protective effect against Alzheimer- and age-related cognitive decline. This APP mutation leads to the reduced production of Aβ with A2T (position in peptide sequence) change (Aβice). In addition, Aβice has the capacity to form protective heterodimers in association with wild-type Aβ. Despite the emerging interest in Aβice during the last decade, the impact of Aβice on events associated with the amyloid cascade has never been reported. First, the effects of Aβice were evaluated in vitro by electrophysiology on hippocampal slices and by studying synapse morphology in cortical neurons. We showed that Aβice protects against endogenous Aβ-mediated synaptotoxicity. Second, as several studies have outlined that a single intracerebral administration of Aβ can worsen Aβ deposition and cognitive functions several months after the inoculation, we evaluated in vivo the long-term effects of a single inoculation of Aβice or Aβ-wild-type (Aβwt) in the hippocampus of transgenic mice (APPswe/PS1dE9) over-expressing Aβ1-42 peptide. Interestingly, we found that the single intra-hippocampal inoculation of Aβice to mice rescued synaptic density and spatial memory losses four months post-inoculation, compared with Aβwt inoculation. Although Aβ load was not modulated by Aβice infusion, the amount of Tau-positive neuritic plaques was significantly reduced. Finally, a lower phagocytosis by microglia of post-synaptic compounds was detected in Aβice-inoculated animals, which can partly explain the increased density of synapses in the Aβice animals. Thus, a single event as Aβice inoculation can improve the fate of AD-associated pathology and phenotype in mice several months after the event. These results open unexpected fields to develop innovative therapeutic strategies against AD.

The bidirectional effects of APPswe on the osteogenic differentiation of MSCs in bone homeostasis by regulating Notch signaling

Amyloid precursor protein (APP), especially Swedish mutant APP (APPswe), is recognized as a significant pathogenic protein in Alzheimer's disease, but limited research has been conducted on the correlation between APPswe and the osteogenic differentiation of mesenchymal stem cells (MSCs). The effects of APPswe and its intracellular and extracellular segments on the osteogenic differentiation of bone morphogenetic protein 2 (BMP2)-induced MSCs were analyzed in this study. Our analysis of an existing database revealed that APP was positively correlated with the osteogenic differentiation of MSCs but negatively correlated with their proliferation and migration. Furthermore, APPswe promoted BMP2-induced osteogenic differentiation of MSCs, while APPswe-C (APPswe without an intracellular segment) had the opposite effect; thus, the intracellular domain of APPswe may be a key factor in promoting the osteogenic differentiation of MSCs. Additionally, both APPswe and APPswe-C inhibited the proliferation and migration of MSCs. Furthermore, the intracellular domain of APPswe inhibited the activity of the Notch pathway by regulating the expression of the Notch intracellular domain to promote the osteogenic differentiation of MSCs. Finally, APPswe-treated primary rat bone marrow MSCs exhibited the most favorable bone repair effect when a GelMA hydrogel loaded with BMP2 was used for in vivo experiments, while APPswe-C had the opposite effect. These findings demonstrate that APPswe promotes the osteogenic differentiation of MSCs by regulating the Notch pathway, but its extracellular segment blocks the self-renewal, proliferation, and migration of MSCs, ultimately leading to a gradual decrease in the storage capacity of MSCs and affecting long-term bone formation.

Epigenetic modifications of DNA and RNA in Alzheimer's disease.

Alzheimer's disease (AD) is a complex neurodegenerative disorder and the most common form of dementia. There are two main types of AD: familial and sporadic. Familial AD is linked to mutations in amyloid precursor protein (APP), presenilin-1 (PSEN1), and presenilin-2 (PSEN2). On the other hand, sporadic AD is the more common form of the disease and has genetic, epigenetic, and environmental components that influence disease onset and progression. Investigating the epigenetic mechanisms associated with AD is essential for increasing understanding of pathology and identifying biomarkers for diagnosis and treatment. Chemical covalent modifications on DNA and RNA can epigenetically regulate gene expression at transcriptional and post-transcriptional levels and play protective or pathological roles in AD and other neurodegenerative diseases.

Emerging structures and dynamic mechanisms of γ-secretase for Alzheimer's disease.

γ-Secretase, called "the proteasome of the membrane," is a membrane-embedded protease complex that cleaves 150+ peptide substrates with central roles in biology and medicine, including amyloid precursor protein and the Notch family of cell-surface receptors. Mutations in γ-secretase and amyloid precursor protein lead to early-onset familial Alzheimer's disease. γ-Secretase has thus served as a critical drug target for treating familial Alzheimer's disease and the more common late-onset Alzheimer's disease as well. However, critical gaps remain in understanding the mechanisms of processive proteolysis of substrates, the effects of familial Alzheimer's disease mutations, and allosteric modulation of substrate cleavage by γ-secretase. In this review, we focus on recent studies of structural dynamic mechanisms of γ-secretase. Different mechanisms, including the "Fit-Stay-Trim," "Sliding-Unwinding," and "Tilting-Unwinding," have been proposed for substrate proteolysis of amyloid precursor protein by γ-secretase based on all-atom molecular dynamics simulations. While an incorrect registry of the Notch1 substrate was identified in the cryo-electron microscopy structure of Notch1-bound γ-secretase, molecular dynamics simulations on a resolved model of Notch1-bound γ-secretase that was reconstructed using the amyloid precursor protein-bound γ-secretase as a template successfully captured γ-secretase activation for proper cleavages of both wildtype and mutant Notch, being consistent with biochemical experimental findings. The approach could be potentially applied to decipher the processing mechanisms of various substrates by γ-secretase. In addition, controversy over the effects of familial Alzheimer's disease mutations, particularly the issue of whether they stabilize or destabilize γ-secretase-substrate complexes, is discussed. Finally, an outlook is provided for future studies of γ-secretase, including pathways of substrate binding and product release, effects of modulators on familial Alzheimer's disease mutations of the γ-secretase-substrate complexes. Comprehensive understanding of the functional mechanisms of γ-secretase will greatly facilitate the rational design of effective drug molecules for treating familial Alzheimer's disease and perhaps Alzheimer's disease in general.

The Effect of Polyphenols on Cellular and Isolated Proteasomes

This study investigated the impact of phenyl-γ-valerolactones (PVLs), key metabolites of flavan-3-ols, on isolated and cellular proteasomes, employing both APPwt and APPmut cellular models of AD. The results demonstrate that PVLs have an inhibitory effect on proteasomes, with the mutated amyloid precursor protein gene (APPmut) cells being more susceptible to this treatment. The interaction between polyphenols and proteasomes presents a promising avenue for understanding cellular health dynamics. This study aimed to investigate the effect of polyphenols on both cellular and isolated proteasomes. The primary objective was to discern the impact of polyphenol exposure on proteasome activity and its potential implications for cellular functions. In vitro studies were conducted using a range of polyphenolic compounds, including flavonoids and phenolic acids. Cellular models were employed to assess the influence of polyphenols on cellular proteasome activity, while isolated proteasomes were subjected to polyphenol treatments to discern direct interactions. The findings revealed significant modulatory effects of polyphenols on both cellular and isolated proteasomes and C2 had strong inhibitory effects on constitutive proteasome activity, with IC50 values ranging from 0.01619 μM to 0.08738 μM. Additional compounds, PGPH and BrAAP, also had inhibitory effects on both proteasome subtypes. Flavonoids demonstrated a dose-dependent enhancement of proteasome activity in cellular models, while phenolic acids exhibited varying effects. Isolated proteasomes responded differently to specific polyphenols, suggesting compound-specific interactions. This study provides novel insights into the intricate relationship between polyphenols and proteasomes, highlighting their potential impact on cellular health. Understanding these interactions could pave the way for targeted interventions in diseases associated with proteasome dysfunction, offering new perspectives on the potential therapeutic roles of polyphenols.

Spatial-Temporal Mapping Reveals the Golgi as the Major Processing Site for the Pathogenic Swedish APP Mutation: Familial APP Mutant Shifts the Major APP Processing Site.

Alzheimer's disease is associated with increased levels of amyloid beta (Aβ) generated by sequential intracellular cleavage of amyloid precursor protein (APP) by membrane-bound secretases. However, the spatial and temporal APP cleavage events along the trafficking pathways are poorly defined. Here, we use the Retention Using Selective Hooks (RUSH) to compare in real time the anterograde trafficking and temporal cleavage events of wild-type APP (APPwt) with the pathogenic Swedish APP (APPswe) and the disease-protective Icelandic APP (APPice). The analyses revealed differences in the trafficking profiles and processing between APPwt and the APP familial mutations. While APPwt was predominantly processed by the β-secretase, BACE1, following Golgi transport to the early endosomes, the transit of APPswe through the Golgi was prolonged and associated with enhanced amyloidogenic APP processing and Aβ secretion. A 20°C block in cargo exit from the Golgi confirmed β- and γ-secretase processing of APPswe in the Golgi. Inhibition of the β-secretase, BACE1, restored APPswe anterograde trafficking profile to that of APPwt. APPice was transported rapidly through the Golgi to the early endosomes with low levels of Aβ production. This study has revealed different intracellular locations for the preferential cleavage of APPwt and APPswe and Aβ production, and the Golgi as the major processing site for APPswe, findings relevant to understand the molecular basis of Alzheimer's disease.

Autosomal Dominant Alzheimer's Disease Mutations in Human Microglia Are Not Sufficient to Trigger Amyloid Pathology in WT Mice but Might Affect Pathology in 5XFAD Mice.

Several genetic variants that affect microglia function have been identified as risk factors for Alzheimer's Disease (AD), supporting the importance of this cell type in disease progression. However, the effect of autosomal dominant mutations in the amyloid precursor protein (APP) or the presenilin (PSEN1/2) genes has not been addressed in microglia in vivo. We xenotransplanted human microglia derived from non-carriers and carriers of autosomal dominant AD (ADAD)-causing mutations in the brain of hCSF1 WT or 5XFAD mice. We observed that ADAD mutations in microglia are not sufficient to trigger amyloid pathology in WT mice. In 5XFAD mice, we observed a non-statistically significant increase in amyloid plaque volume and number of dystrophic neurites, coupled with a reduction in plaque-associated microglia in the brain of mice xenotransplanted with ADAD human microglia compared to mice xenotransplanted with non-ADAD microglia. In addition, we observed a non-statistically significant impairment in working and contextual memory in 5XFAD mice xenotransplanted with ADAD microglia compared to those xenotransplanted with non-ADAD-carrier microglia. We conclude that, although not sufficient to initiate amyloid pathology in the healthy brain, mutations in APP and PSEN1 in human microglia might cause mild changes in pathological and cognitive outcomes in 5XFAD mice in a manner consistent with increased AD risk.

Integration of Microfluidic Devices with Microelectrode Arrays to Functionally Assay Amyloid-β-Induced Synaptotoxicity.

Alzheimer's disease (AD) is a neurodegenerative disease and the most frequent cause of dementia. It is characterized by the accumulation in the brain of two pathological protein aggregates: amyloid-β peptides (Aβ) and abnormally phosphorylated tau. The progressive cognitive decline observed in patients strongly correlates with the synaptic loss. Many lines of evidence suggest that soluble forms of Aβ accumulate into the brain where they cause synapse degeneration. Stopping their spreading and/or targeting the pathophysiological mechanisms leading to synaptic loss would logically be beneficial for the patients. However, we are still far from understanding these processes. Our objective was therefore to develop a versatile model to assay and study Aβ-induced synaptotoxicity. We integrated a microfluidic device that physically isolates synapses from presynaptic and postsynaptic neurons with a microelectrode array. We seeded mouse primary cortical cells in the presynaptic and postsynaptic chambers. After functional synapses have formed in the synaptic chamber, we exposed them to concentrated conditioned media from cell lines overexpressing the wild-type or mutated amyloid precursor protein and thus secreting different levels of Aβ. We recorded the neuronal activity before and after exposition to Aβ and quantified Aβ's effects on the connectivity between presynaptic and postsynaptic neurons. We observed that the application of Aβ on the synapses for 48 h strongly decreased the interchamber connectivity without significantly affecting the neuronal activity in the presynaptic or postsynaptic chambers. Thus, through this model, we are able to functionally assay the impact of Aβ peptides (or other molecules) on synaptic connectivity and to use the latter as a proxy to study Aβ-induced synaptotoxicity. Moreover, since the presynaptic, postsynaptic, and synaptic chambers can be individually targeted, our assay provides a powerful tool to evaluate the involvement of candidate genes in synaptic vulnerability and/or test therapeutic strategies for AD.

The Large Ectodomain of APP Prevents APP from being Directly Cleaved by γ-Secretase.

Alzheimer's disease (AD) is characterized by the deposition of amyloid-β peptide (Aβ) in the brain. Aβ is produced by sequential β- and γ-secretase cleavages of amyloid precursor protein (APP). Clinical trials targeting β- and γ-secretases have all failed, partly because of the strong side effects. The aims of this work were to determine if the direct cleavage of APP by γ-secretase inhibits Aβ production, and to identify γ-cleavage-inhibiting signals within APP that can be targeted to prevent Aβ generation without inhibiting any enzyme. An APP mutant mimicking secreted APPγ was overexpressed in cells to test β-cleavage and Aβ production. APP deletion and truncation mutants were overexpressed in cells to identify the γ-secretase-inhibiting domain. The intracellular transport of the mutants was examined using immunofluorescence. Co-immunoprecipitation was performed to investigate the molecular mechanisms. The APP N-terminal fragment mimicking the direct γ-cleavage product was not cleaved by beta-secretase 1 to produce detectable Aβ. However, in cells, the C-terminal fragments of APP longer than the last 116 residues could not be cleaved by γ-secretase in cells. No deletion mutant was cleaved by γ-secretase. C99, the direct precursor of Aβ, was no longer a γ-secretase substrate when green fluorescent protein was fused to its N-terminus. The large ectodomains prevented access to γ-secretase. Enabling the direct γ-cleavage of APP is a new and valid strategy to reduce Aβ. However, APP does not inhibit γ-cleavage via a specific inhibitory sequence in the ectodomain. Other methods to fulfill the strategy may benefit AD prevention and therapy.

Altered amyloid-β structure markedly reduces gliosis in the brain of mice harboring the Uppsala APP deletion

Deposition of amyloid beta (Aβ) into plaques is a major hallmark of Alzheimer’s disease (AD). Different amyloid precursor protein (APP) mutations cause early-onset AD by altering the production or aggregation properties of Aβ. We recently identified the Uppsala APP mutation (APPUpp), which causes Aβ pathology by a triple mechanism: increased β-secretase and altered α-secretase APP cleavage, leading to increased formation of a unique Aβ conformer that rapidly aggregates and deposits in the brain. The aim of this study was to further explore the effects of APPUpp in a transgenic mouse model (tg-UppSwe), expressing human APP with the APPUpp mutation together with the APPSwe mutation. Aβ pathology was studied in tg-UppSwe brains at different ages, using ELISA and immunohistochemistry. In vivo PET imaging with three different PET radioligands was conducted in aged tg-UppSwe mice and two other mouse models; tg-ArcSwe and tg-Swe. Finally, glial responses to Aβ pathology were studied in cell culture models and mouse brain tissue, using ELISA and immunohistochemistry. Tg-UppSwe mice displayed increased β-secretase cleavage and suppressed α-secretase cleavage, resulting in AβUpp42 dominated diffuse plaque pathology appearing from the age of 5–6 months. The γ-secretase cleavage was not affected. Contrary to tg-ArcSwe and tg-Swe mice, tg-UppSwe mice were [11C]PiB-PET negative. Antibody-based PET with the 3D6 ligand visualized Aβ pathology in all models, whereas the Aβ protofibril selective mAb158 ligand did not give any signals in tg-UppSwe mice. Moreover, unlike the other two models, tg-UppSwe mice displayed a very faint glial response to the Aβ pathology. The tg-UppSwe mouse model thus recapitulates several pathological features of the Uppsala APP mutation carriers. The presumed unique structural features of AβUpp42 aggregates were found to affect their interaction with anti-Aβ antibodies and profoundly modify the Aβ-mediated glial response, which may be important aspects to consider for further development of AD therapies.

Abstract WP291: Cerebral Amyloid Angiopathy Induces Liver Inflammation in Aged Mice

Introduction: Cerebral amyloid angiopathy (CAA) is a chronic age-related neurodegenerative disease, identified by the presence of amyloid-beta (Aβ) deposition within the vasculature of the brain, leading to stroke and progressive cognitive decline. The liver is a key peripheral organ involved in the clearance of excess Aβ in the circulation. However, the role of the brain-liver axis in CAA is unknown. Here, we investigate inflammatory changes in the liver in a murine model of CAA. Methods: Aged (>23 months) male and female Tg-SwDI (CAA) mice harboring Swedish, Dutch, and Iowa mutations of the human amyloid precursor protein were used as a mouse model of CAA along with age-matched wild-type (WT) controls (n=3-7/grp). Hepatic inflammation was analyzed with histological and immunofluorescence imaging. Single cells from liver tissue were isolated and analyzed using flow cytometry. Total RNA was isolated to examine gene expression in the liver using real-time quantitative PCR. Results: Our data showed that CAA increases infiltration of immune cells proximal to liver sinusoids across both sexes compared to WT mice. We found increased macrophages (i.e., F4/80 + cells) in the liver of CAA mice compared to WT controls. Flow cytometry on the liver revealed that female CAA mice had a significant increase in dendritic cells (i.e., CD80 + CD45 + CD11c + cells, *** P <0.001) compared to WT females. Further, we found that Oatp2 , a membrane transporter which mediates hepatocytic uptake of toxic molecules (e.g., Aβ), is associated with sex-specific CAA pathophysiology in the liver. Conclusions: In this study, we found that sex differences may exist in CAA-induced liver inflammation. Further investigations are needed to study how vascular amyloidosis shapes the immune responses and peripheral Aβ clearance in the context of aging and CAA.

Abstract TP28: The Effects of Social Isolation on Cerebral Amyloid Angiopathy

Introduction: Cerebral amyloid angiopathy (CAA) is characterized by amyloid β (Aβ) deposition in the cortical and leptomeningeal vessels, and it is a largely untreatable cause of intracerebral hemorrhage and dementia. Studies estimate a 10-50% prevalence of CAA in the general elderly population, positioning it as one of the strongest vascular contributors to age-related cognitive impairment. With aging, the prevalence of social isolation (SI) also increases. Isolated individuals have an increased risk of Aβ-related cognitive decline and heightened inflammatory response to stress. Yet, whether and how SI exacerbates CAA-induced cognitive decline is unknown. Methods: TgSwDI mice harboring Swedish, Dutch, and Iowa mutations of human amyloid precursor protein were used as a mouse model of CAA. Male and female C57BL6 wildtype (WT) and CAA mice were randomly assigned to paired housing (PH) or SI at 3 months. Neurobehaviors were measured at baseline and every 3 months using the novel object recognition test (NORT), tail suspension test (TST), and fear conditioning (FC). At 12 months, microglia phenotype, vascular structure, and Aβ burden were assessed using flow cytometry and immunostaining. Results: Both WT and CAA isolated animals displayed significantly greater immobility in TST at 9 months post-SI, suggesting a depression-like behavior (n=10-15/grp, p<0.0001). Isolated CAA mice displayed exacerbated cognitive deficits in NORT and FC while WT mice showed intact cognition (n=10-15/grp, p<0.05). Specifically, SI-induced cognitive deficits were more prominent in the female CAA mice compared to males (n=5-8/grp, p<0.01). Sex differences were also observed in CAA mice in frequencies of Aβ-containing endothelial cells (CD31 + ) and vessel-associated microglia (VAM, CD45 int CD11b + CD31 + ) as well as in microglial phagocytosis of Aβ (n=3/grp, p<0.05). SI increased the frequency of Aβ-containing microglia in isolated CAA mice compared to their PH littermates. Conclusion: SI induced behavioral deficits in both WT and CAA mice but exacerbated cognitive decline only in the CAA SI mice. SI also influences microglial phagocytosis of Aβ. Further research is needed to determine the cellular and molecular mechanism underlying SI-induced changes in CAA.

Abstract 20: Axonal Neuropathy and Inflammatory Response in Peripheral Nerves of a Murine Cerebral Amyloid Angiopathy Model

Introduction: Cerebral amyloid angiopathy (CAA) induces intracerebral hemorrhages, small vessel disease, and cognitive decline in elderly individuals. CAA is also associated with slower walking speed and abnormal gait rhythms compared to healthy controls. Little is known regarding the impact of peripheral nervous system abnormalities on CAA-associated gait disturbance. Furthermore, it is unknown whether peripheral nerves pose extracerebral targets of amyloid-related endoneurial inflammation. Hypothesis: Gait disturbance in a CAA model is associated with peripheral neuropathy through endoneurial inflammation related to amyloid accumulation. Methods: Aged (19-24 months) Tg-SwDI mice (CAA mice) of both sexes harboring mutations of human amyloid precursor protein (APP) were used as a CAA model. Age-matched C57BL/6 wild-type (WT) mice were used as controls (n=6-11/grp). Gait disturbance and sensorimotor function were assessed via DigiGait and grip strength testing. Flow cytometry was used to analyze immune cells in the sciatic nerve. Tibial nerve morphometry was performed to assess for neuropathy. Results: CAA mice had weaker grip strength ( CAA: 97.7 ± 17.6 g, WT 111.5 ± 8.1 g, p=0.039 ) and evidence of neuropathic gait disturbances, reflected by increased paw angles ( CAA: 21.1 ± 4.8°, WT 11.7 ± 3.4°, p=0.0002 ) and reduced paw areas ( CAA: 0.4 ± 0.05 cm 2 , WT 0.5 ± 0.06 cm 2 , p=0.013 ) impacting the ground when walking compared to WT mice. Tibial nerve morphometry showed a reduced number of myelinated nerve fibers ( CAA: 1023 ± 230.1, WT 1318 ± 45.8, p=0.0047 ) suggesting potential axonal degeneration in CAA mice. Flow cytometry showed an increase in the count of macrophage (both M1 and M2 subtypes) lineage cells ( M1 CAA: 102.3 ± 29.2, WT 57.9 ± 36.3, p=0.009 ) as well as M1 macrophage associated pro-inflammatory cytokine TNF-α ( CAA: 99.7 ± 28.3, WT 53.8 ± 12.2, p=0.009 ) in sciatic nerves of CAA mice compared to WT mice. Conclusions: CAA mice display an enhanced inflammatory response within the endoneurium which may contribute to observed axonal degeneration, ultimately impairing sensorimotor function and gait. Further studies are needed to unravel the mechanistic interplay between amyloid pathology, endoneurial inflammation, and axonal neuropathy in this CAA model.