ABSTRACT
We previously reported that inducing gamma oscillations with a non-invasive light flicker (gamma entrainment using sensory stimulus or GENUS) impacted pathology in the visual cortex of Alzheimer's disease mouse models. Here, we designed auditory tone stimulation that drove gamma frequency neural activity in auditory cortex (AC) and hippocampal CA1. Seven days of auditory GENUS improved spatial and recognition memory and reduced amyloid in AC and hippocampus of 5XFAD mice. Changes in activation responses were evident in microglia, astrocytes, and vasculature. Auditory GENUS also reduced phosphorylated tau in the P301S tauopathy model. Furthermore, combined auditory and visual GENUS, but not either alone, produced microglial-clustering responses, and decreased amyloid in medial prefrontal cortex. Whole brain analysis using SHIELD revealed widespread reduction of amyloid plaques throughout neocortex after multi-sensory GENUS. Thus, GENUS can be achieved through multiple sensory modalities with wide-ranging effects across multiple brain areas to improve cognitive function.
Subject(s)
Acoustic Stimulation/methods , Alzheimer Disease/therapy , Cognition/physiology , Alzheimer Disease/pathology , Amyloid/metabolism , Amyloid beta-Peptides/metabolism , Animals , Auditory Perception/physiology , Brain/metabolism , Disease Models, Animal , Gamma Rhythm/physiology , Hippocampus/metabolism , Male , Mice , Mice, Inbred C57BL , Microglia/metabolism , Plaque, Amyloid/metabolismABSTRACT
Change history: In this Article, the Acknowledgements section should have included that the work was supported in part by the Cure Alzheimer's Fund (CAF), and the final NIH grant acknowledged should have been 'U01MH119509' instead of 'RF1AG054012'. In Supplementary Table 2, the column labels 'early.pathology.mean' and 'late.pathology.mean' were reversed in each worksheet (that is, columns Y and Z). These errors have been corrected online.
ABSTRACT
Alzheimer's disease is a pervasive neurodegenerative disorder, the molecular complexity of which remains poorly understood. Here, we analysed 80,660 single-nucleus transcriptomes from the prefrontal cortex of 48 individuals with varying degrees of Alzheimer's disease pathology. Across six major brain cell types, we identified transcriptionally distinct subpopulations, including those associated with pathology and characterized by regulators of myelination, inflammation, and neuron survival. The strongest disease-associated changes appeared early in pathological progression and were highly cell-type specific, whereas genes upregulated at late stages were common across cell types and primarily involved in the global stress response. Notably, we found that female cells were overrepresented in disease-associated subpopulations, and that transcriptional responses were substantially different between sexes in several cell types, including oligodendrocytes. Overall, myelination-related processes were recurrently perturbed in multiple cell types, suggesting that myelination has a key role in Alzheimer's disease pathophysiology. Our single-cell transcriptomic resource provides a blueprint for interrogating the molecular and cellular basis of Alzheimer's disease.
Subject(s)
Alzheimer Disease/genetics , Alzheimer Disease/pathology , Single-Cell Analysis , Transcriptome , Aging/genetics , Aging/pathology , Disease Progression , Female , Gene Expression Profiling , Humans , Male , Organ Specificity , Prefrontal Cortex/metabolism , Prefrontal Cortex/pathology , RNA, Messenger/analysis , RNA, Messenger/genetics , Sequence Analysis, RNA , Sex CharacteristicsABSTRACT
Many crowded biomolecular structures in cells and tissues are inaccessible to labelling antibodies. To understand how proteins within these structures are arranged with nanoscale precision therefore requires that these structures be decrowded before labelling. Here we show that an iterative variant of expansion microscopy (the permeation of cells and tissues by a swellable hydrogel followed by isotropic hydrogel expansion, to allow for enhanced imaging resolution with ordinary microscopes) enables the imaging of nanostructures in expanded yet otherwise intact tissues at a resolution of about 20 nm. The method, which we named 'expansion revealing' and validated with DNA-probe-based super-resolution microscopy, involves gel-anchoring reagents and the embedding, expansion and re-embedding of the sample in homogeneous swellable hydrogels. Expansion revealing enabled us to use confocal microscopy to image the alignment of pre-synaptic calcium channels with post-synaptic scaffolding proteins in intact brain circuits, and to uncover periodic amyloid nanoclusters containing ion-channel proteins in brain tissue from a mouse model of Alzheimer's disease. Expansion revealing will enable the further discovery of previously unseen nanostructures within cells and tissues.
Subject(s)
Microscopy , Nanostructures , Animals , Brain/metabolism , Calcium Channels/metabolism , DNA/metabolism , Hydrogels , Mice , Microscopy/methods , Proteins/metabolismABSTRACT
While gene expression profiling has traditionally been the method of choice for large-scale perturbational profiling studies, proteomics has emerged as an effective tool in this context for directly monitoring cellular responses to perturbations. We previously reported a pilot library containing 3400 profiles of multiple perturbations across diverse cellular backgrounds in the reduced-representation phosphoproteome (P100) and chromatin space (Global Chromatin Profiling, GCP). Here, we expand our original dataset to include profiles from a new set of cardiotoxic compounds and from astrocytes, an additional neural cell model, totaling 5300 proteomic signatures. We describe filtering criteria and quality control metrics used to assess and validate the technical quality and reproducibility of our data. To demonstrate the power of the library, we present two case studies where data is queried using the concept of "connectivity" to obtain biological insight. All data presented in this study have been deposited to the ProteomeXchange Consortium with identifiers PXD017458 (P100) and PXD017459 (GCP) and can be queried at https://clue.io/proteomics .
Subject(s)
Antineoplastic Agents/toxicity , Astrocytes/drug effects , Astrocytes/metabolism , Cardiotoxins/toxicity , Protein Kinase Inhibitors/toxicity , Proteomics , Cell Line, Tumor , Humans , Phosphorylation/drug effects , Protein Processing, Post-Translational/drug effects , ProteomeABSTRACT
The epigenome and three-dimensional (3D) genomic architecture are emerging as key factors in the dynamic regulation of different transcriptional programs required for neuronal functions. In this study, we used an activity-dependent tagging system in mice to determine the epigenetic state, 3D genome architecture and transcriptional landscape of engram cells over the lifespan of memory formation and recall. Our findings reveal that memory encoding leads to an epigenetic priming event, marked by increased accessibility of enhancers without the corresponding transcriptional changes. Memory consolidation subsequently results in spatial reorganization of large chromatin segments and promoter-enhancer interactions. Finally, with reactivation, engram neurons use a subset of de novo long-range interactions, where primed enhancers are brought in contact with their respective promoters to upregulate genes involved in local protein translation in synaptic compartments. Collectively, our work elucidates the comprehensive transcriptional and epigenomic landscape across the lifespan of memory formation and recall in the hippocampal engram ensemble.
Subject(s)
Epigenomics , Hippocampus/physiology , Memory/physiology , Mental Recall/physiology , Transcriptome , Animals , Brain Mapping , Memory Consolidation/physiology , Mice , Mice, Transgenic , Neurons/physiology , Synapses/metabolism , Synapses/physiology , Up-Regulation/physiologyABSTRACT
Neuronal and synaptic loss is characteristic in many neurodegenerative diseases, such as frontotemporal dementia and Alzheimer's disease. Recently, we showed that inducing gamma oscillations with visual stimulation (gamma entrainment using sensory stimuli, or GENUS) reduced amyloid plaques and phosphorylated tau in multiple mouse models. Whether GENUS can affect neurodegeneration or cognitive performance remains unknown. Here, we demonstrate that GENUS can entrain gamma oscillations in the visual cortex, hippocampus, and prefrontal cortex in Tau P301S and CK-p25 mouse models of neurodegeneration. Tau P301S and CK-p25 mice subjected to chronic, daily GENUS from the early stages of neurodegeneration showed a preservation of neuronal and synaptic density across multiple brain areas and modified cognitive performance. Our transcriptomic and phosphoproteomic data suggest that chronic GENUS shifts neurons to a less degenerative state, improving synaptic function, enhancing neuroprotective factors, and reducing DNA damage in neurons while also reducing inflammatory response in microglia.
Subject(s)
Gamma Rhythm/physiology , Hippocampus/physiopathology , Neurodegenerative Diseases/physiopathology , Neurons/pathology , Neuroprotection/physiology , Photic Stimulation/methods , Prefrontal Cortex/physiopathology , Visual Cortex/physiopathology , Animals , DNA Damage , Disease Models, Animal , Gene Expression Profiling , Hippocampus/metabolism , Hippocampus/pathology , Inflammation , Mice , Microglia/immunology , Neurodegenerative Diseases/metabolism , Neurodegenerative Diseases/pathology , Neurons/metabolism , Phosphoproteins/metabolism , Prefrontal Cortex/metabolism , Prefrontal Cortex/pathology , Proteomics , Spatial Learning/physiology , Spatial Memory/physiology , Synapses/metabolism , Synapses/pathology , Visual Cortex/metabolism , Visual Cortex/pathologyABSTRACT
Alzheimer's disease (AD) is a progressive, neurodegenerative dementia with no cure. Prominent hypotheses suggest accumulation of beta-amyloid (AĆ) contributes to neurodegeneration and memory loss, however identifying brain regions with early susceptibility to AĆ remains elusive. Using SWITCH to immunolabel intact brain, we created a spatiotemporal map of AĆ deposition in the 5XFAD mouse. We report that subcortical memory structures show primary susceptibility to AĆ and that aggregates develop in increasingly complex networks with age. The densest early AĆ occurs in the mammillary body, septum, and subiculum- core regions of the Papez memory circuit. Previously, early mammillary body dysfunction in AD had not been established. We also show that AĆ in the mammillary body correlates with neuronal hyper-excitability and that modulation using a pharmacogenetic approach reduces AĆ deposition. Our data demonstrate large-tissue volume processing techniques can enhance biological discovery and suggest that subcortical susceptibility may underlie early brain alterations in AD.
Subject(s)
Alzheimer Disease/metabolism , Amyloid beta-Peptides/metabolism , Brain/metabolism , Alzheimer Disease/pathology , Amyloidosis/metabolism , Amyloidosis/pathology , Animals , Brain/pathology , Disease Models, Animal , Disease Progression , Humans , Mice, TransgenicABSTRACT
Although the value of proteomics has been demonstrated, cost and scale are typically prohibitive, and gene expression profiling remains dominant for characterizing cellular responses to perturbations. However, high-throughput sentinel assays provide an opportunity for proteomics to contribute at a meaningful scale. We present a systematic library resource (90 drugs Ć 6 cell lines) of proteomic signatures that measure changes in the reduced-representation phosphoproteome (P100) and changes in epigenetic marks on histones (GCP). A majority of these drugs elicited reproducible signatures, but notable cell line- and assay-specific differences were observed. Using the "connectivity" framework, we compared signatures across cell types and integrated data across assays, including a transcriptional assay (L1000). Consistent connectivity among cell types revealed cellular responses that transcended lineage, and consistent connectivity among assays revealed unexpected associations between drugs. We further leveraged the resource against public data to formulate hypotheses for treatment of multiple myeloma and acute lymphocytic leukemia. This resource is publicly available at https://clue.io/proteomics.
Subject(s)
Databases, Factual , Phosphoproteins/drug effects , Algorithms , Cell Line , Chromatography, Liquid , Datasets as Topic , Gene Expression Regulation , Histone Code , Humans , Mass Spectrometry , Pharmacological and Toxicological Phenomena , Phosphoproteins/metabolism , Proteomics , Signal Transduction , SoftwareABSTRACT
Microglia, the tissue-resident macrophages in the brain, are damage sensors that react to nearly any perturbation, including neurodegenerative diseases such as Alzheimer's disease (AD). Here, using single-cell RNA sequencing, we determined the transcriptome of more than 1,600 individual microglia cells isolated from the hippocampus of a mouse model of severe neurodegeneration with AD-like phenotypes and of control mice at multiple time points during progression of neurodegeneration. In this neurodegeneration model, we discovered two molecularly distinct reactive microglia phenotypes that are typified by modules of co-regulated type I and type II interferon response genes, respectively. Furthermore, our work identified previously unobserved heterogeneity in the response of microglia to neurodegeneration, discovered disease stage-specific microglia cell states, revealed the trajectory of cellular reprogramming of microglia in response to neurodegeneration, and uncovered the underlying transcriptional programs.
Subject(s)
Alzheimer Disease/metabolism , Macrophage Activation , Microglia/metabolism , Transcriptome , Animals , Brain/cytology , Brain/metabolism , Cells, Cultured , Gene Expression Profiling , Interferon Type I/genetics , Interferon-gamma/genetics , Macrophages/metabolism , Mice , Microglia/cytology , Phenotype , Single-Cell AnalysisABSTRACT
Long-term potentiation (LTP) is an enhancement of synaptic strength that may contribute to information storage in the mammalian brain. LTP expression can be regulated by previous synaptic activity, a process known as "metaplasticity." Cell-wide occurrence of metaplasticity may regulate synaptic strength. However, few reports have demonstrated metaplasticity at synapses that are silent during activity at converging synaptic inputs. We describe a novel form of cell-wide metaplasticity in hippocampal area CA1. Low-frequency stimulation (LFS) decreased the stability of long-lasting LTP ["late" LTP (L-LTP)] induced later at the same inputs (homosynaptic inhibition) and at other inputs converging on the same postsynaptic cells (heterosynaptic inhibition). Significantly, heterosynaptic inhibition of L-LTP also occurred across basal and apical dendrites ("heterodendritic" inhibition). Because transient early LTP (E-LTP) was not affected by previous LFS, we examined the effects of LFS on the consolidation of E-LTP to L-LTP. The duration of E-LTP induced at one set of inputs can be extended by capturing L-LTP-associated gene products generated by previous activity at other inputs to the same postsynaptic neurons. LFS applied homosynaptically or heterosynaptically before L-LTP induction did not impair synaptic capture by subsequent E-LTP stimulation, suggesting that LFS does not impair L-LTP-associated transcription. In contrast, LFS applied just before E-LTP (homosynaptically or heterosynaptically) prevented synaptic tagging, and capture of L-LTP expression. Thus, LFS inhibits synaptic tagging to impair expression of subsequent L-LTP. Such anterograde inhibition represents a novel way in which synaptic activity can regulate the expression of future long-lasting synaptic plasticity in a cell-wide manner.
Subject(s)
Hippocampus/physiology , Long-Term Potentiation/physiology , Neural Inhibition/physiology , Neuronal Plasticity/physiology , Synapses/physiology , Animals , Dendrites/metabolism , Electric Stimulation/methods , Excitatory Postsynaptic Potentials , Female , Gene Expression , In Vitro Techniques , Long-Term Synaptic Depression/physiology , Mice , Mice, Inbred C57BL , Nerve Tissue Proteins/biosynthesis , Time Factors , Transcription, Genetic/physiologyABSTRACT
The hippocampus is an area of the brain involved in learning and memory. It contains parallel excitatory pathways referred to as the trisynaptic pathway (which carries information as follows: entorhinal cortex --> dentate gyrus --> CA3 --> CA1 --> entorhinal cortex) and the monosynaptic pathway (entorhinal cortex --> CA1 --> entorhinal cortex). We developed a generally applicable tetanus toxin-based method for transgenic mice that permits inducible and reversible inhibition of synaptic transmission and applied it to the trisynaptic pathway while preserving transmission in the monosynaptic pathway. We found that synaptic output from CA3 in the trisynaptic pathway is dispensable and the short monosynaptic pathway is sufficient for incremental spatial learning. In contrast, the full trisynaptic pathway containing CA3 is required for rapid one-trial contextual learning, for pattern completion-based memory recall, and for spatial tuning of CA1 cells.
Subject(s)
Hippocampus/physiology , Maze Learning , Pyramidal Cells/physiology , Synaptic Transmission , Action Potentials , Animals , Crosses, Genetic , Dentate Gyrus/physiology , Electrophysiology , Entorhinal Cortex/physiology , Excitatory Postsynaptic Potentials , Female , Interneurons/physiology , Male , Mental Recall , Metalloendopeptidases/genetics , Mice , Mice, Transgenic , Neural Pathways , Tetanus Toxin/geneticsABSTRACT
The late-phase of long-term potentiation (L-LTP) in hippocampal area CA1 requires gene expression and de novo protein synthesis but it is expressed in an input-specific manner. The 'synaptic tag' theory proposes that gene products can only be captured and utilized at synapses that have been 'tagged' by previous activity. The mechanisms underlying synaptic tagging, and its activity dependence, are largely undefined. Previously, we reported that low-frequency stimulation (LFS) decreases the stability of L-LTP in a cell-wide manner by impairing synaptic tagging. We show here that a phosphatase inhibitor, okadaic acid, blocked homosynaptic and heterosynaptic inhibition of L-LTP by prior LFS. In addition, prior LFS homosynaptically and heterosynaptically impaired chemically induced synaptic facilitation elicited by forskolin/3-isobutyl-1-methylxanthine, suggesting that there is a cell-wide dampening of cAMP/protein kinase A (PKA) signaling concurrent with phosphatase activation. We propose that prior LFS impairs expression of L-LTP by inhibiting synaptic tagging through its actions on the cAMP/PKA pathway. In support of this notion, we show that hippocampal slices from transgenic mice that have genetically reduced hippocampal PKA activity display impaired synaptic capture of L-LTP. An inhibitor of PKA, KT-5720, also blocked synaptic capture of L-LTP. Moreover, pharmacological activation of the cAMP/PKA pathway can produce a synaptic tag to capture L-LTP expression, resulting in persistent synaptic facilitation. Collectively, our results show that PKA is critical for synaptic tagging and for input-specific L-LTP. PKA-mediated signaling can be constrained by prior episodes of synaptic activity to regulate subsequent L-LTP expression and perhaps control the integration of multiple synaptic events over time.
Subject(s)
Cyclic AMP-Dependent Protein Kinases/physiology , Long-Term Potentiation , Synapses/physiology , 1-Methyl-3-isobutylxanthine/pharmacology , Animals , Carbazoles/pharmacology , Colforsin/pharmacology , Cyclic AMP/physiology , Cyclic AMP-Dependent Protein Kinases/antagonists & inhibitors , Electric Stimulation , Female , Hippocampus/physiology , In Vitro Techniques , Indoles/pharmacology , Mice , Mice, Inbred C57BL , Mice, Transgenic , Okadaic Acid/pharmacology , Pyrroles/pharmacology , Signal TransductionABSTRACT
Spaced training is generally more effective than massed training for learning and memory, but the molecular mechanisms underlying this trial spacing effect remain poorly characterized. One potential molecular basis for the trial spacing effect is the differential modulation, by distinct temporal patterns of neuronal activity, of protein synthesis-dependent processes that contribute to the expression of specific forms of synaptic plasticity in the mammalian brain. Long-term potentiation (LTP) is a type of synaptic modification that may be important for certain forms of memory storage in the mammalian brain. To explore the role of protein synthesis in the trial spacing effect, we assessed the protein synthesis dependence of hippocampal LTP induced by 100-Hz tetraburst stimulation delivered to mouse hippocampal slices in either a temporally massed (20-s interburst interval) or spaced (5-min interburst interval) fashion. To extend our studies to the behavioral level, we trained mice in fear conditioning using either a massed or spaced training protocol and examined the sensitivity of long-term memory to protein synthesis inhibition. Larger LTP was induced by spaced stimulation in hippocampal slices. This improvement of synaptic potentiation following temporally spaced synaptic stimulation in slices was attenuated by bath application of an inhibitor of protein synthesis. Further, the maintenance of LTP induced by spaced synaptic stimulation was more sensitive to disruption by anisomycin than the maintenance of LTP elicited following massed stimulation. Temporally spaced behavioral training improved long-term memory for contextual but not for cued fear conditioning, and this enhancement of memory for contextual fear was also protein synthesis dependent. Our data reveal that altering the temporal spacing of synaptic stimulation and behavioral training improved hippocampal LTP and enhanced contextual long-term memory. From a broad perspective, these results suggest that the recruitment of protein synthesis-dependent processes important for long-term memory and for long-lasting forms of LTP can be modulated by the temporal profiles of behavioral training and synaptic stimulation.