Project description:Alzheimer's disease (AD) exhibits imbalance between neuronal excitation and inhibition, likely secondary to interneuron dysfunction. To reveal underlying mediators, we profiled the transcriptome of neuronal subtypes in 5XFAD versus control mice at early- and late-stage disease. Pooled analysis of neuron types showed expected pathways at early-stage (RNA and protein processing pathways) versus late-stage (neurodegenerative pathways) disease. Early-stage interneurons exhibited alterations in AD-related RNA and protein pathways along with canonical neurodegenerative pathways. Early-stage excitatory neurons, however, showed changes in axon guidance and synapse pathways, without representation of neurodegenerative pathways. Classical neurodegenerative pathways were represented only in late-stage excitatory neurons. Late-stage interneurons instead featured neuronal and synapse pathways along with cellular, cancer, and infection pathways. Our results suggest earlier neurodegenerative pathway involvement in interneurons, represented in excitatory neurons only at later stages, possibly indicating earlier inhibitory neuron involvement. These transcriptomic profiles offer insight into potential AD pathophysiology and therapeutic targets.

Project description:Alzheimer’s disease (AD) is a chronic ageing related neurodegenerative disease which is characterized by loss of synapses and neurons in the vulnerable brain regions. Expression perturbations of amyloid β (Aβ) and tau protein in the brain are two hallmarks of AD. Aβ is abnormally generated from amyloid precursor protein (APP) which is broadly distributed in different brain regions including the hippocampus and cortex. It is believed that increased Aβ expression plays a causative role in the early stage of AD pathology. Aβ protein interacts with the signaling pathways that control the phosphorylation of the microtubule-associated protein tau, which eventually disrupts the neuronal circuitry as well as network connectivity leading to neurodegenerative processes observed in AD. In addition, substantial molecular and neurodegenerative changes occur in the initial stage of AD even before the cognitive symptoms are evident, which makes the early diagnosis of AD vital to any timely disease stabilization and treatment. However, despite myriad efforts and substantial progress in the field to decipher the molecular mechanisms of disease onset and its progression, specific causes underlying AD pathology remain ill-defined. There is an urgent need to identify novel mechanism based interventional approaches that can stop, or slow down, the progression of AD. Therefore, it is important to improve the knowledge of the early AD and have a better understanding of the underlying molecular mechanisms induced by Aβ. In this study, we performed comparative quantitative proteomics on different brain regions of 2.5 months old APP/PS1 mice (hippocampus, frontal cortex, parietal cortex and cerebellum) in order to investigate the early stage impact of AD. Although over 5000 proteins were identified in all regions, the proteome response across regions was greatly varied. As expected, the greatest proteome perturbation was detected in the hippocampus and frontal cortex (AD-susceptible brain regions), compared to only 155 changed proteins in the cerebellum (less vulnerable region to AD). Increased expression of APP protein was identified in all brain regions. The expression of the majority of the other proteins between hippocampus and cortex areas was not similar, highlighting differential effects of the disease on different brain regions. A series of AD associated markers and pathways were identified as overexpressed in the hippocampus including glutamatergic synapse, GABAergic synapse, retrograde endocannabinoid signaling, long-term potentiation, and calcium signaling. In contrast, the expression of same proteins and pathways was negatively regulated in frontal and parietal cortex regions. Additionally, an increased expression of proteins associated with the oxidative phosphorylation pathway in hippocampus was not evident in the two cortices. Interestingly, an increased expression of proteins involved with myelination, neurofilament cytoskeleton organization, and glutathione metabolism was identified in cortex areas, while these were reduced in the hippocampus. The results obtained from this study highlight important information on brain region specific protein expression changes occurring in the early stages of AD.

Project description:The innate immune system plays essential roles in brain development, including the remodeling of neuronal synapses. Innate lymphocytes are the most recently discovered member of the innate immune arsenal, whose developmental expansion and activation make them potential mediators of brain-immune communication during synapse formation. Here we show that group 2 innate lymphoid cells (ILC2s) and their cytokine Interleukin-13 (IL-13) signal directly to inhibitory interneurons to increase inhibitory synapse density in the developing brain. ILC2s expanded and produced IL-13 in the developing brain meninges. Loss of ILC2s or IL-13 signaling to interneurons decreased inhibitory, but not excitatory, cortical synapses. Conversely, ILC2s and IL-13 were sufficient to increase inhibitory synapses. Loss of this signaling pathway led to selective impairments in social interaction. These data define a type 2 neuroimmune circuit in early life that shapes inhibitory synapse development and behavior.

Project description:Cell surface receptors, including erythropoietin-producing hepatocellular A4 (EphA4), are important in regulating hippocampal synapse loss, which is the key driver of memory decline in Alzheimer’s disease (AD). However, the cellular-specific roles and mechanisms of EphA4 are unclear. Here, we show that EphA4 expression is elevated in hippocampal CA1 astrocytes in AD conditions. Specific knockout of astrocytic EphA4 ameliorates excitatory synapse loss in the hippocampus in AD transgenic mouse models. Single-nucleus RNA sequencing analysis revealed that EphA4 inhibition specifically decreases a reactive astrocyte subpopulation with enriched complement signaling, which are characteristics associated with synapse elimination by astrocytes in AD. Importantly, astrocytic EphA4 knockout in an AD transgenic mouse model decreases complement tagging on excitatory synapses and excitatory synapses within astrocytes. These findings suggest an important role of EphA4 in the astrocyte-mediated elimination of excitatory synapses in AD and highlight the crucial role of astrocytes in hippocampal synapse maintenance in AD.

Project description:Alzheimer’s disease (AD) is an unremitting neurodegenerative disorder characterized by cerebral amyloid-β (Aβ) accumulation and gradual decline in cognitive function. Changes in brain energy metabolism arise in the preclinical phase of AD, suggesting an important metabolic component of early AD pathology. Neurons and astrocytes function in close metabolic collaboration, which is essential for the recycling of neurotransmitters in the synapse. However, how this metabolic interplay may be affected during the early stages of AD development has not been sufficiently investigated. Here, we provide an integrative analysis of cellular metabolism during the early stages of Aβ accumulation in the cerebral cortex and hippocampus of the 5xFAD mouse model of AD. Our electrophysiological examination revealed an increase in spontaneous excitatory signaling in hippocampal brain slices of 5xFAD mice. This hyperactive neuronal phenotype coincided with decreased hippocampal TCA cycle metabolism mapped by stable 13C isotope tracing. Particularly, reduced astrocyte TCA cycle activity led to decreased glutamine synthesis, in turn hampering neuronal GABA synthesis in the 5xFAD hippocampus. In contrast, cerebral cortical slices of 5xFAD mice displayed an elevated capacity for oxidative glucose metabolism suggesting a metabolic compensation. When we explored the brain proteome and metabolome of the 5xFAD mice, we found limited changes, supporting that the functional metabolic disturbances between neurons and astrocytes are early events in AD pathology. In addition, we show that synaptic mitochondrial and glycolytic function was impaired selectively in the 5xFAD hippocampus, whereas non-synaptic mitochondrial function was maintained. These findings were supported by ultrastructural analyses demonstrating disruptions in mitochondrial morphology, particularly in the 5xFAD hippocampus. Collectively, our study reveals complex region and cell specific metabolic adaptations, in the early stages of amyloid pathology, which may be fundamental for the progressing synaptic dysfunction in AD.

Project description:Synapse loss and glial activation are hallmarks of Alzheimer's disease (AD). In Tau P301S transgenic mice, the complement pathway contributes to neuronal damage through microglial elimination of synapses. Here, we used unbiased proteomic profiling of postsynaptic density (PSD) fractions from Tau P301S mice in C1q-WT versus C1q knockout backgrounds to identify C1q-dependent changes at synapses. Integrative multi-omics analysis revealed that astrocyte- and microglia- specific proteins are increased in Tau P301S synapse fractions with age and in a C1q-dependent manner. The same set of glial proteins (including C1q, C4, Gpnmb, and S100a4) is elevated in human AD synaptic fractions, and C4 levels are raised in cerebrospinal fluid (CSF) from AD patients. Besides microglia, we show that astrocytes contribute substantially to excitatory and inhibitory synapse engulfment in Tau P301S hippocampus. Based on staining of synapse markers within lysosomes, astrocytes showed preference for excitatory synapses whereas microglia preferred to engulf inhibitory synapse markers. Genetic deletion of C1q reduced astrocytic eating of excitatory and inhibitory synapses in Tau P301S mice, and rescued synapse density. Together, our data indicate that astrocytes contact and phagocytose synapses in a C1q- dependent manner and thereby contribute to synapse loss and neurodegeneration in AD.

Project description:Cell surface receptors, including erythropoietin-producing hepatocellular A4 (EphA4), are important in regulating hippocampal synapse loss, which is the key driver of memory decline in Alzheimer’s disease (AD). However, the cellular-specific roles and mechanisms of EphA4 are unclear. Here, we show that EphA4 expression is elevated in hippocampal CA1 astrocytes in AD conditions. Specific knockout of astrocytic EphA4 ameliorates excitatory synapse loss in the hippocampus in AD transgenic mouse models. Single-nucleus RNA sequencing analysis revealed that EphA4 inhibition specifically decreases a reactive astrocyte subpopulation with enriched complement signaling, which are characteristics associated with synapse elimination by astrocytes in AD. Importantly, astrocytic EphA4 knockout in an AD transgenic mouse model decreases complement tagging on excitatory synapses and excitatory synapses within astrocytes. These findings suggest an important role of EphA4 in the astrocyte-mediated elimination of excitatory synapses in AD and highlight the crucial role of astrocytes in hippocampal synapse maintenance in AD.

Project description:Alzheimer’s Disease is a devastating and an irreversible neurodegenerative disease currently afflicting 50 million individuals worldwide, a number expected to escalate three-fold over the next 25 years. Preventative treatment is of dire importance, and yet, cellular mechanisms underlying early regional vulnerability in Alzheimer’s Disease remain unknown. In human patients with Alzheimer’s Disease, the earliest observed pathophysiological correlate to cognitive decline is hyperexcitability. In mouse models, early hyperexcitability has been shown in the cortical region first impacted by Alzheimer’s Disease. The origin of hyperexcitability in early stage-disease and why it preferentially emerges in specific regions is unclear. Using cortical-region and cell-type- specific proteomics and patch-clamp electrophysiology, we uncovered differential susceptibility to human-specific APP in a model of sporadic Alzheimer’s Disease. Shockingly, our findings reveal that early entorhinal hyperexcitability may result from intrinsic vulnerability of parvalbumin interneurons, prior to changes in surrounding excitatory neurons. This study suggests early disease interventions addressing non-excitatory cell-types may protect regions first vulnerable to pathological symptoms of Alzheimer’s Disease and downstream cognitive decline.

Project description:Alzheimer’s disease (AD) is characterized by the selective vulnerability of specific neuronal populations, the molecular signatures of which are largely unknown. To identify and characterize selectively vulnerable neuronal populations, we used single-nucleus RNA sequencing to profile the caudal entorhinal cortex and the superior frontal gyrus – brain regions where neurofibrillary inclusions and neuronal loss occur early and late in AD, respectively – from individuals spanning the neuropathological progression of AD. We identified RORB as a marker of selectively vulnerable excitatory neurons in the entorhinal cortex, and subsequently validated their depletion and selective susceptibility to neurofibrillary inclusions during disease progression using quantitative neuropathological methods. We also discovered an astrocyte subpopulation, likely representing reactive astrocytes, characterized by decreased expression of genes involved in homeostatic functions. Our characterization of selectively vulnerable neurons in AD paves the way for future mechanistic studies of selective vulnerability and potential therapeutic strategies for enhancing neuronal resilience. The brain tissue used in this study were sourced from the Biobank for Aging Studies (LIM-22) in the Department of Pathology at the University of Sao Paulo, as well as from the Neurodegenerative Diseases Brain Bank in the Memory and Aging Center at the University of California, San Francisco. Detailed neuropathological, clinical and genetic data are available under request. Please contact gerolab@gmail.com and lea.grinberg@ucsf.edu.

Project description:Persistent DNA double-strand breaks (DSBs) in neurons are an early pathological hallmark of neurodegenerative diseases including Alzheimer’s Disease (AD) with the potential to disrupt genome integrity. We show increased mosaic structural variations and gene fusions in neurons burdened with DSBs in the CK-p25 inducible mouse model of neurodegeneration. Next, we used full-transcript single-nucleus RNA-seq across 47 human post-mortem prefrontal cortex and find that excitatory neurons in AD are enriched for mosaic gene fusions. In addition, gene fusions are particularly enriched in excitatory neurons with senescence and DNA repair gene signatures. Neurons enriched for DSBs also have elevated levels of cohesin along with progressive multiscale disruption of the 3D genome organization aligned with transcriptional changes in synaptic and neuronal development genes. Overall, this study demonstrates the disruption of genome stability and the 3D genome organization by DSBs in neurons as pathological steps in the progression of neurodegenerative diseases.