Project description:Synapse dysfunction is an early event of Alzheimer’s disease (AD). It is caused by multiple cellular and pathological factors such as Amyloid beta, p-tau, inflammation, and aging. However, the exact molecular mechanism of synapse dysfunction in AD is largely unknown. Therefore, to understand the molecular basis of synapse dysfunction in AD, we conducted a high throughput multi-omics analysis of the synaptosome fraction in postmortem brain samples from AD patients and cognitively normal individuals. First, microRNA and mRNA HiSeq analysis were performed on the synaptosomes extracted from the postmortem brains of unaffected control (UC) individuals and AD patients. Next, we conducted the mass spectrometry analysis of synaptosomal proteins in the same sample group of HC and AD. The transcriptomic and proteomic profiling of synaptosome showed the significant deregulation of miRNA, mRNA and protein signatures in AD vs HC. Further, we used an integrated transcriptomic and proteomic approach to understand the molecular interactions of deregulated synapse miRNAs, mRNAs, and proteins in the same samples of AD and HC. Multi-omics integration analysis of synapse miRNAs-mRNAs-proteins revealed the involvement of omics targets in several biological processes and molecular functions such as signal transduction, protein binding, GABAergic synapse, and synaptic vesicle cycle, etc. Our study unveiled synapse-centered novel omics candidates that could be potential therapeutic targets to restore synapse dysfunction in AD.

Project description:There has been increasing interest in the quantification and characterization of messages and proteins at the synapse, due to its importance in neurodegenerative disease, most notably Alzheimer’s disease. Here, we report the transcriptomic and proteomic changes that occur in synaptosomes from frontal cortices of Sod2 null mice. Constitutively null Sod2 mice were differentially dosed with the synthetic catalytic antioxidant EUK-189, which can extend the lifespan of these mice, as well as uncover or prevent neurodegeneration due to endogenous oxidative stress. This approach facilitated insight into quantification of trafficked messages and proteins to the synaptosome. We used two complementary methods to investigate the nature of the synaptosome under oxidative stress; either whole genome gene expression microarrays or mass spectrometry-based proteomics using isobaric tagging for relative and absolute quantitation (iTRAQ) of proteins. We have characterized the relative enrichments of gene ontologies at both gene and protein expression that occur due to mitochondrial oxidative stress in the synaptosome, which may lead to new avenues of investigation in understanding the regulation of the synaptic function in normal and diseased states. As a result of using these approaches, we report for the first time an activation of the mTOR pathway in synaptosomes isolated from Sod2 null mice, confirmed by an upregulation of the phosphorylation of 4E-BP1. mRNA was extracted from synaptosome samples of individual mice from each genotype/treatment group (N=9-11 per group/treatment). 200ng of the purified total RNA was then amplified one round using Ambion’s Illumina RNA Amplification Kit, to prepare cRNA for labeling and hybridization to Illumina’s MouseRef-8 v2.0 expression bead chips as per the manufacturers instructions (Illumina, San Diego, CA, USA).

Project description:There has been increasing interest in the quantification and characterization of messages and proteins at the synapse, due to its importance in neurodegenerative disease, most notably Alzheimer’s disease. Here, we report the transcriptomic and proteomic changes that occur in synaptosomes from frontal cortices of Sod2 null mice. Constitutively null Sod2 mice were differentially dosed with the synthetic catalytic antioxidant EUK-189, which can extend the lifespan of these mice, as well as uncover or prevent neurodegeneration due to endogenous oxidative stress. This approach facilitated insight into quantification of trafficked messages and proteins to the synaptosome. We used two complementary methods to investigate the nature of the synaptosome under oxidative stress; either whole genome gene expression microarrays or mass spectrometry-based proteomics using isobaric tagging for relative and absolute quantitation (iTRAQ) of proteins. We have characterized the relative enrichments of gene ontologies at both gene and protein expression that occur due to mitochondrial oxidative stress in the synaptosome, which may lead to new avenues of investigation in understanding the regulation of the synaptic function in normal and diseased states. As a result of using these approaches, we report for the first time an activation of the mTOR pathway in synaptosomes isolated from Sod2 null mice, confirmed by an upregulation of the phosphorylation of 4E-BP1.

Project description:The role of microglia cells in Alzheimer’s disease (AD) is well recognized, however their molecular and functional diversity remain unclear. Here we isolated amyloid plaque-containing (using labelling with methoxy–XO4, XO4+) and non-containing (XO4-) microglia from an AD mouse model. Transcriptomics analysis identified different transcriptional trajectories in ageing and AD mice. XO4+ microglial transcriptomes demonstrated dysregulated expression of genes associated with late onset AD. We further showed that the transcriptional program associated with XO4+ microglia from mice is present in a subset of human microglia isolated from brains of individuals with AD. XO4- microglia displayed transcriptional signatures associated with accelerated ageing and contained more intracellular post-synaptic material than XO4+ microglia, despite reduced active synaptosome phagocytosis. We identified HIF1α as potentially regulating synaptosome phagocytosis in vitro using primary human microglia, and BV2 mouse microglial cells. Together these findings provide insight into molecular mechanisms underpinning the functional diversity of microglia in AD.

Project description:Synapse loss and memory decline are the primary features of neurodegenerative dementia. However, molecular underpinnings that drive memory loss remain largely unknown. Here, we report that FAM69C is a novel kinase critically involved in neurodegenerative dementia. Biochemical analyses uncovered that FAM69C is a serine/threonine kinase. We generated the Fam69c knockout mice, and showed by single-cell RNA sequencing that FAM69C deficiency drives cell-type-specific transcriptional changes relevant to synapse dysfunction. Electrophysiological, morphological and behavioral experiments demonstrated impairments in synaptic plasticity, dendritic spine density and memory in Fam69c knockout mice, as well as stress-induced neuronal death. Phosphoproteomic characterizations revealed FAM69C substrates involved in synaptic structure and function. Finally, reduced levels of FAM69C were found in postmortem brains of AD. Our study demonstrates that FAM69C is a protective regulator of memory and suggests FAM69C as a potential therapeutic target for memory loss in neurodegenerative dementia.

Project description:Shank3 protein is a core organizer of the macromolecular complex in excitatory postsynapses, and its defects cause numerous synaptopathies including autism spectrum disorders. Although Shank3 function as a postsynaptic scaffold is well established, other potential mechanisms how Shank3 broadly modulates the postsynaptic proteome are relatively unexplored. To understand potential contribution of increased proteins synthesis to the proteomic change in TG striatal synaptosome, we performed RNA-seq analyses on both whole synaptosomal and synaptic polysome-enriched fractions. Comparative analyses showed a positive correlation only between polysome-associated transcriptome and up-regulated proteome in TG striatal synaptosome.

Project description:The molecular composition of the excitatory synapse is incompletely defined due to its dynamic nature across developmental stages and neuronal populations. To address this gap, we apply proteomic mass spectrometry to characterize the synapse in multiple biological models including the fetal human brain and hiPSC-derived neurons. To prioritize the identified proteins, we develop an orthogonal multi-omic screen of genomic, transcriptomic, interactomic, and structural data. This data-driven framework identifies proteins with key molecular features intrinsic to the synapse, including characteristic patterns of biophysical interactions and cross-tissue expression. The integrated proteomic and multi-omic analysis captures synaptic proteins across developmental stages and experimental systems, including 492 proteins that have not been documented previously. We further investigate three such proteins that are associated with neurodevelopmental disorders – the CUL3 E3 ubiquitin ligase, the DDX3X and YBX1 nucleic-acid binding factors – by mapping their networks of physically interacting synapse proteins or transcripts. Our study demonstrates the potential of an integrated multi-omic approach to systematically and more comprehensively resolve the synaptic architecture.

Project description:Oligodendrocytes (OLs) and myelin are critical for normal brain function and they have been implicated in neurodegeneration. Human neuroimaging studies have demonstrated that alterations in axons and myelin occur early in Alzheimer’s Disease (AD) course. However, the molecular mechanism underlying the role of OLs in AD remains largely unknown. In this study, we systematically interrogated OL-enriched gene networks constructed from large-scale genomic, transcriptomic, and proteomic data in human AD postmortem brain samples. These robust OL networks were highly enriched for genes associated with AD risk variants, including BIN1. We corroborated the structure of the AD OL coexpression and gene-gene interaction networks through ablation of genes identified as key drivers of the networks, including UGT8, CNP, MYRF, PLP1, NPC1, and NDGR1. Perturbations of these key drivers not only caused dysregulation in their associated network neighborhoods, but also mimicked pathways of gene expression dysregulation seen in human AD postmortem brain samples. In particular, the OL subnetwork controlled by the AD risk gene PSEN1 was strongly dysregulated in AD, suggesting a potential role of PSEN1 in disrupting the myelination pathway towards the onset of AD. In summary, this study built and systematically validated the first comprehensive molecular blueprint of OL dysregulation in AD, and identified key OL- and myelination-related genes and networks as potential candidate targets for the future development of AD therapies.

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:Parkinson’s disease (PD) is a prevalent neurodegenerative disorder where recent evidence suggests pathogenesis may be mediated by inflammatory processes. The molecular architecture of the disease remains to be fully elucidated. We performed single-nucleus transcriptomics and unbiased proteomics using postmortem tissue obtained from the prefrontal cortex of 12 individuals with late-stage PD and age-matched controls. We analyzed ~80,000 nuclei and identified eight major cell types, including brain-resident T cells, each with distinct transcriptional changes in line with the known genetics of PD. By analyzing Lewy body pathology in the same postmortem tissue, we found that α-synuclein pathology is inversely correlated with chaperone expression in excitatory neurons. Examining cell-cell interactions, we found a selective abatement of neuron-astrocyte interactions and enhanced neuroinflammation. Proteomic analyses of the same brains identified synaptic proteins in prefrontal cortex that were preferentially downregulated in PD. Strikingly, comparing this dataset to a regionally similar published analysis for Alzheimer’s disease (AD), we found no common differentially expressed genes in neurons, but identified many shared differentially expressed genes in glial cells, suggesting that disease etiology in PD and AD are likely distinct. These data are presented as a resource for interrogating the molecular and cellular basis of PD and other neurodegenerative diseases.