Soluble Tau Research Articles

New Hypothesis on Enhancing β-Sheet Formation during the Tau Fragment Dimer Transition from a Flexible Monomer: Insights into Primary Nucleation Processes by Histidine Behaviors.

Slight perturbations in pH can have significant effects on the primary nucleation processes of the tau protein. The behaviors of histidine due to its pivotal role in modulating H-bonding network interactions and electrostatic interactions have garnered considerable attention, as it can influence the structural characteristics and aggregation properties. However, the nucleation mechanisms and related intermediates are still unclear. In the current study, we performed nine independent replica exchange molecular dynamics simulations to investigate dimer formation involving R3(εδ) in conjunction with the R1, R2, and R4 monomers. Our findings substantiate that, in comparison to R1-R3(εδ) and R4-R3(εδ) systems, the R2-R3(εδ) systems consistently manifest the highest averaged β-sheet content, with the fundamental feature of R3(εδ) promoting R2 rearrangement. Our comprehensive analysis reveals that high-β-sheet-rich systems exhibit a conserved three/five β-strand structure. In these β-strand-rich systems, one chain [R1/R2/R4 or R3(εδ)] with robust intrachain H-bonding interactions coordinates with another chain through interchain H-bonding interactions, contributing to the overall stability. Furthermore, we discuss distinct histidine behaviors, including backbone/side chain interactions and donor/acceptor roles. This study provides a comprehensive understanding of the aggregation propensities of soluble tau oligomers and sheds light on the primary nucleation mechanism. It contributes to a new perspective for understanding protein folding and misfolding.

CSF complement proteins are elevated in prodromal to moderate Alzheimer's disease patients and are not altered by the anti-tau antibody semorinemab.

Growing evidence suggests a role for neuroinflammation in Alzheimer's disease (AD). We investigated complement pathway activity in AD patient cerebrospinal fluid (CSF) and evaluated its modulation by the anti-tau antibody semorinemab. Immunoassays were applied to measure CSF complement proteins C4, factor B (FB), C3 and their cleavage fragments C4a, C3a, and factor Bb (Bb) in AD patients and a separate cognitively unimpaired (CU) cohort. All measured CSF complement proteins were increased in AD versus CU subjects, with C4a displaying the most robust increase. Finally, semorinemab did not have a significant pharmacodynamic effect on CSF complement proteins. Elevated levels of CSF C4a, C4, C3a, C3, Bb, and FB are consistent with complement activation in AD brains. Despite showing a reduction in CSF soluble tau species, semorinemab did not impact complement protein levels or activity. Further studies are needed to determine the value of complement proteins as neuroinflammation biomarkers in AD. Cerebrospinal fluid (CSF) complement proteins C4a, C3a, Bb, C4, C3, and factor B levels were increased in Alzheimer's disease (AD) patients compared to a separate cognitively unimpaired (CU) cohort. Baseline CSF complement protein levels were correlated with neuro-axonal degeneration and glial activation biomarkers in AD patients. The investigational anti-tau antibody semorinemab did not impact CSF complement protein levels or activity relative to the placebo arm.

Co-opting templated aggregation to degrade pathogenic tau assemblies and improve motor function

Protein aggregation causes a wide range of neurodegenerative diseases. Targeting and removing aggregates, but not the functional protein, is a considerable therapeutic challenge. Here, we describe a therapeutic strategy called "RING-Bait," which employs an aggregating protein sequence combined with an E3 ubiquitin ligase. RING-Bait is recruited into aggregates, whereupon clustering dimerizes the RING domain and activates its E3 function, resulting in the degradation of the aggregate complex. We exemplify this concept by demonstrating the specific degradation of tau aggregates while sparing soluble tau. Unlike immunotherapy, RING-Bait is effective against both seeded and cell-autonomous aggregation. RING-Bait removed tau aggregates seeded from Alzheimer's disease (AD) and progressive supranuclear palsy (PSP) brain extracts and was also effective in primary neurons. We used a brain-penetrant adeno-associated virus (AAV) to treat P301S tau transgenic mice, reducing tau pathology and improving motor function. A RING-Bait strategy could be applied to other neurodegenerative proteinopathies by replacing the Bait sequence to match the target aggregate.

Phosphorylation at serine 214 correlates with tau seeding activity in an age-dependent manner in two mouse models for tauopathies and is required for tau transsynaptic propagation.

Pathological aggregation and propagation of hyperphosphorylated and aberrant forms of tau are critical features of the clinical progression of Alzheimer's disease and other tauopathies. To better understand the correlation between these pathological tau species and disease progression, we profiled the temporal progression of tau seeding activity and the levels of various phospho- and conformational tau species in the brains of two mouse models of human tauopathies. Our findings indicate that tau seeding is an early event that occurs well before the appearance of AT8-positive NFT. Specifically, we observed that tau phosphorylation in serine 214 (pTau-Ser214) positively correlates to tau seeding activity during disease progression in both mouse models. Furthermore, we found that the histopathology of pTau-Ser214 appears much earlier and has a distinct pattern and compartmentalization compared to the pathology of AT8, demonstrating the diversity of tau species within the same region of the brain. Importantly, we also observed that preventing the phosphorylation of tau at Ser214 significantly decreases tau propagation in mouse primary neurons, and seeding activity in a Drosophila model of tauopathy, suggesting a role for this tau phosphorylation in spreading pathological forms of tau. Together, these results suggest that the diverse spectrum of soluble pathological tau species could be responsible for the distinct pathological properties of tau and that it is critical to dissect the nature of the tau seed in the context of disease progression.

Virus-like particle (VLP)-based vaccine targeting tau phosphorylated at Ser396/Ser404 (PHF1) site outperforms phosphorylated S199/S202 (AT8) site in reducing tau pathology and restoring cognitive deficits in the rTg4510 mouse model of tauopathy.

Tauopathies, including Alzheimer's disease (AD) and Frontotemporal Dementia (FTD), are histopathologically defined by the aggregation of hyperphosphorylated pathological tau (pTau) as neurofibrillary tangles in the brain. Site-specific phosphorylation of tau occurs early in the disease process and correlates with progressive cognitive decline, thus serving as targetable pathological epitopes for immunotherapeutic development. Previously, we developed a vaccine (Qβ-pT181) displaying phosphorylated Thr181 tau peptides on the surface of a Qβ bacteriophage virus-like particle (VLP) that induced robust antibody responses, cleared pathological tau, and rescued memory deficits in a transgenic mouse model of tauopathy. Here we report the characterization and comparison of two additional Qβ VLP-based vaccines targeting the dual phosphorylation sites Ser199/Ser202 (Qβ-AT8) and Ser396/Ser404 (Qβ-PHF1). Both Qβ-AT8 and Qβ-PHF1 vaccines elicited high-titer antibody responses against their pTau epitopes. However, only Qβ-PHF1 rescued cognitive deficits, reduced soluble and insoluble pathological tau, and reactive microgliosis in a 4-month rTg4510 model of FTD. Both sera from Qβ-AT8 and Qβ-PHF1 vaccinated mice were specifically reactive to tau pathology in human AD post-mortem brain sections. These studies further support the use of VLP-based immunotherapies to target pTau in AD and related tauopathies and provide potential insight into the clinical efficacy of various pTau epitopes in the development of immunotherapeutics.

The Enigma of Tau Protein Aggregation: Mechanistic Insights and Future Challenges.

Tau protein misfolding and aggregation are pathological hallmarks of Alzheimer's disease and over twenty neurodegenerative disorders. However, the molecular mechanisms of tau aggregation in vivo remain incompletely understood. There are two types of tau aggregates in the brain: soluble aggregates (oligomers and protofibrils) and insoluble filaments (fibrils). Compared to filamentous aggregates, soluble aggregates are more toxic and exhibit prion-like transmission, providing seeds for templated misfolding. Curiously, in its native state, tau is a highly soluble, heat-stable protein that does not form fibrils by itself, not even when hyperphosphorylated. In vitro studies have found that negatively charged molecules such as heparin, RNA, or arachidonic acid are generally required to induce tau aggregation. Two recent breakthroughs have provided new insights into tau aggregation mechanisms. First, as an intrinsically disordered protein, tau is found to undergo liquid-liquid phase separation (LLPS) both in vitro and inside cells. Second, cryo-electron microscopy has revealed diverse fibrillar tau conformations associated with different neurodegenerative disorders. Nonetheless, only the fibrillar core is structurally resolved, and the remainder of the protein appears as a "fuzzy coat". From this review, it appears that further studies are required (1) to clarify the role of LLPS in tau aggregation; (2) to unveil the structural features of soluble tau aggregates; (3) to understand the involvement of fuzzy coat regions in oligomer and fibril formation.

Selection of lansoprazole from an FDA-approved drug library to inhibit the Alzheimer's disease seed-dependent formation of tau aggregates.

The efficacy of current treatments is still insufficient for Alzheimer's disease (AD), the most common cause of Dementia. Out of the two pathological hallmarks of AD amyloid-β plaques and neurofibrillary tangles, comprising of tau protein, tau pathology strongly correlates with the symptoms of AD. Previously, screening for inhibitors of tau aggregation that target recombinant tau aggregates have been attempted. Since a recent cryo-EM analysis revealed distinct differences in the folding patterns of heparin-induced recombinant tau filaments and AD tau filaments, this study focused on AD seed-dependent tau aggregation in drug repositioning for AD. We screened 763 compounds from an FDA-approved drug library using an AD seed-induced tau aggregation in SH-SY5Y cell-based assay. In the first screening, 180 compounds were selected, 72 of which were excluded based on the results of lactate dehydrogenase assay. In the third screening with evaluations of soluble and insoluble tau, 38 compounds were selected. In the fourth screening with 3 different AD seeds, 4 compounds, lansoprazole, calcipotriene, desogestrel, and pentamidine isethionate, were selected. After AD seed-induced real-time quaking-induced conversion, lansoprazole was selected as the most suitable drug for repositioning. The intranasal administration of lansoprazole for 4 months to AD seed-injected mice improved locomotor activity and reduced both the amount of insoluble tau and the extent of phosphorylated tau-positive areas. Alanine replacement of the predicted binding site to an AD filament indicated the involvement of Q351, H362, and K369 in lansoprazole and C-shaped tau filaments. These results suggest the potential of lansoprazole as a candidate for drug repositioning to an inhibitor of tau aggregate formation in AD.

Novel ultrasensitive immunoassay for the selective quantification of tau oligomers and related soluble aggregates.

Tau aggregation into paired helical filaments and neurofibrillary tangles is characteristic of Alzheimer's disease (AD) and related disorders. However, biochemical assays for the quantification of soluble, earlier-stage tau aggregates are lacking. We describe an immunoassay that is selective for tau oligomers and related soluble aggregates over monomers. A homogeneous (single-antibody) immunoassay was developed using a novel anti-tau monoclonal antibody and validated with recombinant and brain tissue-derived tau. The assay signals were concentration dependent for recombinant tau aggregates in solution but not monomers, and recognized peptides within, but not outside, the aggregation-prone microtubule binding region. The signals in inferior and middle frontal cortical tissue homogenates increased with neuropathologically determined Braak staging, and were higher in insoluble than soluble homogenized brain fractions. Autopsy-verified AD gave stronger signals than other neurodegenerative diseases. The quantitative oligomer/soluble aggregate-specific assay can identify soluble tau aggregates, including oligomers, from monomers in human and in vitro biospecimens. The aggregation of tau to form fibrils and neurofibrillary tangles is a key feature of Alzheimer's disease. However, biochemical assays for the quantification of oligomers/soluble aggregated forms of tau are lacking. We developed a new assay that preferentially binds to soluble tau aggregates, including oligomers and fibrils, versus monomers. The assay signal increased corresponding to the total protein content, Braak staging, and insolubility of the sequentially homogenized brain tissue fractions in an autopsy-verified cohort. The assay recognized tau peptides containing the microtubule binding region but not those covering the N- or C-terminal regions only.

P-tau217 correlates with neurodegeneration in Alzheimer’s disease, and targeting p-tau217 with immunotherapy ameliorates murine tauopathy

Neuronal loss is the central issue in Alzheimer's disease (AD), yet no treatment developed so far can halt AD-associated neurodegeneration. Here, we developed a monoclonal antibody (mAb2A7) against 217 site-phosphorylated human tau (p-tau217) and observed that p-tau217 levels positively correlated with brain atrophy and cognitive impairment in AD patients. Intranasal administration efficiently delivered mAb2A7 into male PS19 tauopathic mouse brain with target engagement and reduced tau pathology/aggregation with little effect on total soluble tau. Further, mAb2A7 treatment blocked apoptosis-associated neuronal loss and brain atrophy, reversed cognitive deficits, and improved motor function in male tauopathic mice. Proteomic analysis revealed that mAb2A7 treatment reversed alterations mainly in proteins associated with synaptic functions observed in murine tauopathy and AD brain. An antibody (13G4) targeting total tau also attenuated tau-associated pathology and neurodegeneration but impaired the motor function of male tauopathic mice. These results implicate p-tau217 as a potential therapeutic target for AD-associated neurodegeneration.

Hippocampal hyperphosphorylated tau-induced deficiency is rescued by L-type calcium channel blockade.

Aging and Alzheimer's disease are associated with chronic elevations in neuronal calcium influx via L-type calcium channels. The hippocampus, a primary memory encoding structure in the brain, is more vulnerable to calcium dysregulation in Alzheimer's disease. Recent research has suggested a link between L-type calcium channels and tau hyperphosphorylation. However, the precise mechanism of L-type calcium channel-mediated tau toxicity is not understood. In this study, we seeded a human tau pseudophosphorylated at 14 amino acid sites in rat hippocampal cornu ammonis 1 region to mimic soluble pretangle tau. Impaired spatial learning was observed in human tau pseudophosphorylated at 14 amino acid sites-infused rats as early as 1-3 months and worsened at 9-10 months post-infusion. Rats infused with wild-type human tau exhibited milder behavioural deficiency only at 9-10 months post-infusion. No tangles or plaques were observed in all time points examined in both human tau pseudophosphorylated at 14 amino acid sites and human tau-infused brains. However, human tau pseudophosphorylated at 14 amino acid sites-infused hippocampus exhibited a higher amount of tau phosphorylation at S262 and S356 than the human tau-infused rats at 3 months post-infusion, paralleling the behavioural deficiency observed in human tau pseudophosphorylated at 14 amino acid sites-infused rats. Neuroinflammation indexed by increased Iba1 in the cornu ammonis 1 was observed in human tau pseudophosphorylated at 14 amino acid sites-infused rats at 1-3 but not 9 months post-infusion. Spatial learning deficiency in human tau pseudophosphorylated at 14 amino acid sites-infused rats at 1-3 months post-infusion was paralleled by decreased neuronal excitability, impaired NMDA receptor-dependent long-term potentiation and augmented L-type calcium channel-dependent long-term potentiation at the cornu ammonis 1 synapses. L-type calcium channel expression was elevated in the soma of the cornu ammonis 1 neurons in human tau pseudophosphorylated at 14 amino acid sites-infused rats. Chronic L-type calcium channel blockade with nimodipine injections for 6 weeks normalized neuronal excitability and synaptic plasticity and rescued spatial learning deficiency in human tau pseudophosphorylated at 14 amino acid sites-infused rats. The early onset of L-type calcium channel-mediated pretangle tau pathology and rectification by nimodipine in our model have significant implications for preclinical Alzheimer's disease prevention and intervention.

Pathogenic soluble tau peptide disrupts endothelial calcium signaling and vasodilation in the brain microvasculature

The accumulation of the microtubule-associated tau protein in and around blood vessels contributes to brain microvascular dysfunction through mechanisms that are incompletely understood. Delivery of nutrients to active neurons in the brain relies on capillary calcium (Ca2+) signals to direct blood flow. The initiation and amplification of endothelial cell Ca2+ signals require an intact microtubule cytoskeleton. Since tau accumulation in endothelial cells disrupts native microtubule stability, we reasoned that tau-induced microtubule destabilization would impair endothelial Ca2+ signaling. We tested the hypothesis that tau disrupts the regulation of local cerebral blood flow by reducing endothelial cell Ca2+ signals and endothelial-dependent vasodilation. We used a pathogenic soluble tau peptide (T-peptide) model of tau aggregation and mice with genetically encoded endothelial Ca2+ sensors to measure cerebrovascular endothelial responses to tau exposure. T-peptide significantly attenuated endothelial Ca2+ activity and cortical capillary blood flow in vivo. Further, T-peptide application constricted pressurized cerebral arteries and inhibited endothelium-dependent vasodilation. This study demonstrates that pathogenic tau alters cerebrovascular function through direct attenuation of endothelial Ca2+ signaling and endothelium-dependent vasodilation.

Regional AT-8 reactive tau species correlate with intracellular Aβ levels in cases of low AD neuropathologic change

The amyloid cascade hypothesis states that Aβ aggregates induce pathological changes in tau, leading to neurofibrillary tangles (NFTs) and cell death. A caveat with this hypothesis is the spatio-temporal divide between plaques and NFTs. This has been addressed by the inclusion of soluble Aβ and tau species in the revised amyloid cascade hypothesis. Nevertheless, despite the potential for non-plaque Aβ to contribute to tau pathology, few studies have examined relative correlative strengths between total Aβ, plaque Aβ and intracellular Aβ with tau pathology within a single tissue cohort. Employing frozen and fixed frontal cortex grey and white matter tissue from non-AD controls (Con; n = 39) and Alzheimer’s disease (AD) cases (n = 21), biochemical and immunohistochemical (IHC) measures of Aβ and AT-8 phosphorylated tau were assessed. Biochemical native-state dot blots from crude tissue lysates demonstrated robust correlations between total Aβ and AT-8 tau, when considered as a combined cohort (Con and AD) and when as Con and AD cases, separately. In contrast, no associations between Aβ plaques and AT-8 were reported when using IHC measurements in either Con or AD cases. However, when intracellular Aβ was measured via the Aβ specific antibody MOAB-2, a correlative relationship with AT-8 tau was reported in non-AD controls but not in AD cases. Collectively the data suggests that accumulating intracellular Aβ may influence AT-8 pathology, early in AD-related neuropathological change. Despite the lower levels of phospho-tau and Aβ in controls, the robust correlative relationships observed suggest a physiological association of Aβ production and tau phosphorylation, which may be modified during disease. This study is supportive of a revised amyloid cascade hypothesis and demonstrates regional associative relationships between tau pathology and intracellular Aβ, but not extracellular Aβ plaques.

Sedimentation and Laser Light Scattering Methods for Quantifying Synthetic Tau Aggregation Propensity.

Tau aggregation assays detect and quantify the conversion of soluble tau monomers into species having filamentous or oligomeric structure. Assays for filamentous aggregates in cross-β-sheet conformation leverage optical, biochemical, or biophysical methods, each with their own advantages and throughput capacity. Here we provide protocols for two medium-throughput assays based on sedimentation and laser light scattering and compare their performance, their utility for characterizing tau aggregation dynamics, and their limitations relative to other approaches. Additionally, a protocol for transmission electron microscopy analysis is updated so as to be compatible with the truncated tau variants that have emerged as powerful tools for interrogating the structural basis of tau polymorphism. Together these methods contribute to a rich tool kit for interrogating tau aggregation kinetics and propensity over a wide range of experimental conditions.

Traumatic brain injury derived pathological tau polymorphs induce the distinct propagation pattern and neuroinflammatory response in wild type mice

The misfolding and aggregation of the tau protein into neurofibrillary tangles constitutes a central feature of tauopathies. Traumatic brain injury (TBI) has emerged as a potential risk factor, triggering the onset and progression of tauopathies. Our previous research revealed distinct polymorphisms in soluble tau oligomers originating from single versus repetitive mild TBIs. However, the mechanisms orchestrating the dissemination of TBI brain-derived tau polymorphs (TBI-BDTPs) remain elusive. In this study, we explored whether TBI-BDTPs could initiate pathological tau formation, leading to distinct pathogenic trajectories. Wild-type mice were exposed to TBI-BDTPs from sham, single-blast (SB), or repeated-blast (RB) conditions, and their memory function was assessed through behavioral assays at 2- and 8-month post-injection. Our findings revealed that RB-BDTPs induced cognitive and motor deficits, concurrently fostering the emergence of toxic tau aggregates within the injected hippocampus. Strikingly, this tau pathology propagated to cortical layers, intensifying over time. Importantly, RB-BDTP-exposed animals displayed heightened glial cell activation, NLRP3 inflammasome formation, and increased TBI biomarkers, particularly triggering the aggregation of S100B, which is indicative of a neuroinflammatory response. Collectively, our results shed light on the intricate mechanisms underlying TBI-BDTP-induced tau pathology and its association with neuroinflammatory processes. This investigation enhances our understanding of tauopathies and their interplay with neurodegenerative and inflammatory pathways following traumatic brain injury.

Cerebral organoids with chromosome 21 trisomy secrete Alzheimer’s disease-related soluble aggregates detectable by single-molecule-fluorescence and super-resolution microscopy

Understanding the role of small, soluble aggregates of beta-amyloid (Aβ) and tau in Alzheimer’s disease (AD) is of great importance for the rational design of preventative therapies. Here we report a set of methods for the detection, quantification, and characterisation of soluble aggregates in conditioned media of cerebral organoids derived from human iPSCs with trisomy 21, thus containing an extra copy of the amyloid precursor protein (APP) gene. We detected soluble beta-amyloid (Aβ) and tau aggregates secreted by cerebral organoids from both control and the isogenic trisomy 21 (T21) genotype. We developed a novel method to normalise measurements to the number of live neurons within organoid-conditioned media based on glucose consumption. Thus normalised, T21 organoids produced 2.5-fold more Aβ aggregates with a higher proportion of larger (300–2000 nm2) and more fibrillary-shaped aggregates than controls, along with 1.3-fold more soluble phosphorylated tau (pTau) aggregates, increased inflammasome ASC-specks, and a higher level of oxidative stress inducing thioredoxin-interacting protein (TXNIP). Importantly, all this was detectable prior to the appearance of histological amyloid plaques or intraneuronal tau-pathology in organoid slices, demonstrating the feasibility to model the initial pathogenic mechanisms for AD in-vitro using cells from live genetically pre-disposed donors before the onset of clinical disease. Then, using different iPSC clones generated from the same donor at different times in two independent experiments, we tested the reproducibility of findings in organoids. While there were differences in rates of disease progression between the experiments, the disease mechanisms were conserved. Overall, our results show that it is possible to non-invasively follow the development of pathology in organoid models of AD over time, by monitoring changes in the aggregates and proteins in the conditioned media, and open possibilities to study the time-course of the key pathogenic processes taking place.

Magnetic resonance investigation of conformational responses of tau protein to specific phosphorylation

Intrinsically disordered proteins (IDPs) are known to adopt many rapidly interconverting structures, making it difficult to pinpoint the specific conformational states that are relevant for their function. Tau is an important IDP, and its conformation is known to be affected by post-translational modifications (PTMs), such as phosphorylation. To investigate the effect of specific phosphorylation on full-length Tau's dynamic global conformation, we employed a combination of nuclear magnetic resonance-based paramagnetic relaxation interference methods and electron paramagnetic resonance spectroscopy. By reproducing the AT8 epitope, comprising exclusive phosphorylation at residues S202 and T205, we were able to identify conformations specific to phosphorylated Tau, which exhibited a tendency towards less compact states. These mechanistic details are of significance to understand the path leading from soluble Tau to the ordered structure of Tau fibers. This approach proved to be successful for studying the conformational changes of (phosphorylated) full-length Tau and can potentially be extended to the study of other IDPs that undergo various PTMs.

GFAP Upregulation by Astrocytes May Attenuate Phospho‐Tau Levels in a Tauopathy Mouse Model

AbstractBackgroundAstrocytes react to amyloid‐β plaques and phospho‐tau (pTau) neurofibrillary tangles in the Alzheimer’s disease brain but their net effect on these Alzheimer’s neuropathological hallmarks remains controversial. A well‐known feature of these so‐called “reactive astrocytes” is the upregulation of the intermediate filament glial fibrillary acidic protein (GFAP), which is thought to be necessary for astrocyte process motility and glial scar formation. Here we asked whether this cytoskeletal remodeling helps reactive astrocytes control the burden of pTau species and/or protect synapses and neurons.MethodWe overexpressed human GFAP isoform 1 specifically in astrocytes of 4‐month‐old, sex‐balanced, THY‐Tau22 mice (Thy1.2‐MAPT G272V/P301S 1N4R, GFAP mice, n = 11)—when neurofibrillary tangles start to appear in the hippocampal CA1 subfield—using a viral transfer strategy with single retro‐orbital intravenous injection of AAV‐PHP.B (2.5×1011 vg) and the gfaABC1D promoter. We euthanized the mice at 11 months of age (i.e., prior to the tauopathy plateau) and performed immunohistochemical and/or biochemical analysis of astrocyte, tau, and synaptic markers. Negative control groups consisted of THY‐Tau22 littermates injected with either phosphate‐buffered saline (PBS mice, n = 9) or an AAV‐PHP.B vector encoding the enhanced green fluorescent protein (EGFP mice, n = 10).ResultsImmunohistochemistry confirmed the astrocyte‐specific expression of human GFAP with an apparent integration in their intermediate filament network. We observed statistically significant reductions or marginally significant trends toward decrease in hippocampal SDS‐soluble levels AT8/pTauSer202/Thr205 and AT8‐immunoreactive area fraction, and a shift of AT180/pTauThr231 from SDS‐soluble (decreased) to TBS‐soluble (increased) hippocampal protein fractions, in GFAP vs. EGFP and/or PBS mice, but no changes in soluble or insoluble total tau or AT270/pTauThr181 across groups. In the cortex, we detected no changes in soluble or insoluble total tau, AT8/pTauSer202/Thr205, or AT270/pTauThr181 levels, nor in AT8‐immunoreactive area. Lastly, we found no significant differences across groups in brain weight, cortical or hippocampal areas, nor in the cortical levels of synaptophysin, Psd95, or the glutamate transporters Eaat1/Glast‐1 and Eaat2/Glt‐1.ConclusionOur findings indicate that GFAP upregulation by astrocytes—a classic feature of reactive astrogliosis—may attenuate neuronal pTau burden in a tauopathy mouse model. Ongoing work will further elucidate whether this aspect of reactive astrocytes impacts pTau‐induced neurodegeneration.

The AD/ADRD Interdisciplinary Research Network on Biologically Active Tau Aggregate Polymorphs from Alzheimer’s Disease and Related Dementias

AbstractBackgroundTauopathies, including Alzheimer’s disease (AD), are characterized by intracellular lesions composed of aggregated and post‐translationally modified tau proteins. Methods for preparation and biochemical characterization of stable filaments from various tauopathies are well established. In contrast, methods for preparation of soluble oligomeric tau aggregates have not been standardized to the same degree. Additionally, the structures of oligomers which associate most closely with disease propagation and toxicity, are not fully established. The AD/ADRD Resource Network aims to isolate structurally vetted tau filaments and oligomers from human tauopathy cases and distribute them to the research community. In addition, it seeks to bank and distribute detection reagents and associated protocols. The overall mission of the network is to support impactful tauopathy research.MethodTauopathies, including Alzheimer’s disease (AD), are characterized by intracellular lesions composed of aggregated and post‐translationally modified tau proteins. Methods for preparation and biochemical characterization of stable filaments from various tauopathies are well established. In contrast, methods for preparation of soluble oligomeric tau aggregates have not been standardized to the same degree. Additionally, the structures of oligomers which associate most closely with disease propagation and toxicity, are not fully established. The AD/ADRD Resource Network aims to isolate structurally vetted tau filaments and oligomers from human tauopathy cases and distribute them to the research community. In addition, it seeks to bank and distribute detection reagents and associated protocols. The overall mission of the network is to support impactful tauopathy research.ResultProtocols for simultaneous isolation of oligomeric and filamentous tau aggregates have been developed along with analytical and quantitative methods to estimate sample heterogenicity and stability. Resource Network members are establishing cross‐laboratory analytical benchmarks for experiments to ensure rigor and reproducibility of results.ConclusionThe AD/ADRD Research Network banks rigorously validated preparations of structurally vetted tau aggregates along with directed protocols and reagents. Dissemination of these reagents is expected to maximize rigor and reproducibility of basic research involving tau protein aggregates.

A role of tau‐induced astrocyte dysfunction and senescence in AD

AbstractBackgroundUnder certain conditions and during aging, cellular stress and damage can trigger cellular senescence, an irreversible state of cell cycle arrest accompanied by the expression of proinflammatory mediators known collectively as the “senescent‐associated secretory phenotype” (SASP). In Alzheimer’s disease (AD), neuronal tau becomes hyperphosphorylated and misfolded, forming pathogenic soluble aggregates (tau oligomers) and destabilizing the microtubule cytoskeleton. Pathogenic soluble tau is released from neurons during neuronal activation and is transmitted in a prion‐like fashion to postsynaptic cells. In addition to neurons, tau is expressed in a variety of brain cell types including astrocytes. In the present study, we tested the central hypothesis that soluble pathogenic tau can be transmitted to astrocytes and that tau transmission to astrocytes induces cytoskeleton destabilization and cellular dysfunction, contributing to the progression of AD.MethodsTo test the molecular consequences of tau transmission, we treated primary human astrocytes with purified tau oligomers. We used advanced biochemical tools, immunocytochemistry, and live‐cell microscopy to measure cell and nuclear size, cell cycle arrest, and SASP activation. We also co cultured human astrocytes undergoing tau‐induced senescence with primary mouse or non‐human primate neurons to determine the functional impact of senescent astrocytes on neurons, then utilized immunocytochemistry and 3D image analyses to measure parameters of dendrite and spine morphology.ResultsWe found that pathogenic soluble tau is readily transmitted to primary human astrocytes, and that pathogenic tau transmission triggers phosphorylation of endogenous astrocyte tau, leading to the destabilization of the microtubule cytoskeleton. Further, we found that transmission of pathogenic tau to astrocytes potently upregulated multiple markers of cellular senescence, demonstrating for the first time tau‐induced astrocyte senescence. Density of dendritic spines and dendritic area were pronouncedly decreased in neurons co‐cultured with astrocytes undergoing tau‐induced senescence.ConclusionWe showed transmission of pathogenic tau to human astrocytes and that this event triggers astrocyte senescence in mouse models of AD tauopathy. Our data suggest that senescent astrocytes may be critical mediators of neuronal dysfunction in AD tauopathy.

Memory dysfunction in mild cognitive impairment (MCI) and early Alzheimer disease (AD) dementia is closely associated with synapse loss, and shows significant correlation with pathological tau in synapses and inflammatory glial cell responses in postmortem human brain

AbstractBackgroundSynapse density loss is among the strongest histopathological correlates of dementia in AD. Prodromal stages of AD, comprising amnestic MCI and mild AD dementia, represent the most promising timepoints for interventions aimed at attaining efficacious neurobiological and clinical effects. Yet, the understanding of other contributing neuropathologic changes in these prodromal disease stages and their impact on early cognitive dysfunction remains limited.MethodsWe studied the visual cortex of 28 demented and non‐demented human brains who had died at Braak III‐IV stages of NFT pathology, and who showed a comparable β‐amyloid plaque burden and absence of NFT deposits in the studied brain region, and a group of age‐matched healthy controls. We used immunohistochemical analyses with artificial intelligence quantifications, expansion microscopy, synaptosome extractions, and Western blotting, to assess associations between antemortem MMSE scores and synapse densities, glial cell phenotypes, and pathological tau.ResultsWe found a significant loss of presynapses (Synapsin 1+), excitatory postsynapses (PSD95+), and colocalized synapses (Synapsin1‐PSD95+) in the brains of demented compared to non‐demented and controls. Moreover, we observed an association between excitatory synapse loss and memory dysfunction (MMSE score) as well as rate of disease progression (MMSE loss/time). MMSE scores were further associated with increase in tau oligomers (TOC1+) and phospho‐tau (AT270+) in synaptosomes, but not with 4G8+ β‐amyloid burden. Additionally, disease severity and rate of progression were significantly correlated with inflammatory glial changes.ConclusionsOur data suggest that excitatory synapse loss could serve as an early and robust neuropathologic correlate of disease severity and rate of progression from MCI stages of the disease, and be a closer and better determinant of cognitive decline than β‐amyloid and tau deposits. Moreover, early increases in soluble tau in synapses together with local inflammatory glial cell responses could drive development of incipient changes in memory function and serve as potential early biomarkers. Our results point to the importance of early detection and interventions aimed at synapse preservation from prodromal stages of AD, and suggest soluble tau and inflammatory glial cell changes as key targets in the early AD phases.