Molecular characterization of selectively vulnerable neurons in Alzheimer’s Disease

Leng, Kun; Li, Emmy; Eser, Rana; Piergies, Antonia M.H.; Sit, Rene; Tan, Michelle; Neff, Norma; Li, Song Hua; Rodriguez, Roberta Diehl; Suemoto, Cláudia Kimie; Leite, Renata Elaine Paraízo; Pasqualucci, Carlos Augusto; Seeley, William W.; Spina, Salvatore; Heinsen, Helmut; Grinberg, Lea T.; Kampmann, Martin

doi:10.1101/2020.04.04.025825

Cited by 19 publications

(29 citation statements)

References 98 publications

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“…Using bMIND, we estimated sample-level CTS expression and detected CTS-DEGs related to AD with FDR < 0.05 (Supplemental Table S1). Similar to the findings based on snRNA-seq of AD (Mathys et al, 2019), most identified CTS-DEGs were from excitatory neurons, a finding that comports with the observed selective vulnerability of excitatory neurons in the brain of AD samples (Leng et al, 2020). We compared the ExN-DEGs identified by the snRNA-seq study (Mathys et al, 2019) and bMIND from the three bulk datasets (Fig.…”

Section: Cts Differential Expression Analysis Of Brain Tissue From Alsupporting

confidence: 62%

Bayesian estimation of cell-type-specific gene expression per bulk sample with prior derived from single-cell data

Wang

Roeder

Devlin

2020

Preprint

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When assessed over a large number of samples, bulk RNA sequencing provides reliable data for gene expression at the tissue level. Single-cell RNA sequencing (scRNA-seq) deepens those analyses by evaluating gene expression at the cellular level. Both data types lend insights into disease etiology. With current technologies, however, scRNA-seq data are known to be noisy. Moreover, constrained by costs, scRNA-seq data are typically generated from a relatively small number of subjects, which limits their utility for some analyses, such as identification of gene expression quantitative trait loci (eQTLs). To address these issues while maintaining the unique advantages of each data type, we develop a Bayesian method (bMIND) to integrate bulk and scRNA-seq data. With a prior derived from scRNA-seq data, we propose to estimate sample-level cell-type-specific (CTS) expression from bulk expression data. The CTS expression enables large-scale sample-level downstream analyses, such as detecting CTS differentially expressed genes (DEGs) and eQTLs. Through simulations, we demonstrate that bMIND improves the accuracy of sample-level CTS expression estimates and power to discover CTS-DEGs when compared to existing methods. To further our understanding of two complex phenotypes, autism spectrum disorder and Alzheimer’s disease, we apply bMIND to gene expression data of relevant brain tissue to identify CTS-DEGs. Our results complement findings for CTS-DEGs obtained from snRNA-seq studies, replicating certain DEGs in specific cell types while nominating other novel genes in those cell types. Finally, we calculate CTS-eQTLs for eleven brain regions by analyzing GTEx V8 data, creating a new resource for biological insights.

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Section: Cts Differential Expression Analysis Of Brain Tissue From Alsupporting

confidence: 62%

Bayesian estimation of cell-type-specific gene expression per bulk sample with prior derived from single-cell data

Wang

Roeder

Devlin

2020

Preprint

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“…Subclustering of astrocyte nuclei revealed four subpopulations of cells with one subcluster called Ast1 enriched with AD cells that upregulated GLUL and the AD risk gene CLU (Mathys et al 2019) (Table 1), previously found upregulated in reactive astrocytes in response to neurodegeneration (Shin et al 2006). Recent singlenucleus sequencing of the entorhinal cortex and the superior frontal gyrus from human healthy brains (n = 3), early (n = 4) and advanced (n = 3) stages of AD also revealed an astrocyte subpopulation expressing higher levels of GFAP, called GFAP-high (Leng et al 2021). GFAP-high astrocytes upregulate CD44 and TNC, both involved in interactions with the extracellular matrix; as well as HSPB1 and HSP90AA1, chaperones involved in proteostasis.…”

Section: Astrocyte Genes and Altered Molecular Pathways In Admentioning

confidence: 90%

“…GFAP-high astrocytes upregulate CD44 and TNC, both involved in interactions with the extracellular matrix; as well as HSPB1 and HSP90AA1, chaperones involved in proteostasis. Interestingly, GFAP-high astrocytes downregulated genes involved in glutamate and GABA homeostasis (SLC1A2, SLC1A3, GLUL and SLC6A11) and synaptic adhesion/maintenance (NRXN1, CADM2, PTN and GPC5), indicating they may have compromised homeostatic function (Leng et al 2021) (Table 1).…”

Section: Astrocyte Genes and Altered Molecular Pathways In Admentioning

confidence: 99%

Astrocytes in Alzheimer´s Disease: Pathological Significance and Molecular Pathways

Preman

Alfonso-Triguero

Alberdi

et al. 2021

Preprint

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Astrocytes perform a wide variety of essential functions defining normal operation of the nervous system, and are active contributors to the pathogenesis of neurodegenerative disorders such as Alzheimer among others. Recent data provide compelling evidence that distinct reactive astrocyte states are associated with specific stages of Alzheimer´s disease. The advent of transcriptomics technologies enables rapid progress in the characterisation of such pathological astrocyte states. In this review, we provide an overview of the origin, main functions, molecular and morphological features of astrocytes in physiological as well as pathological conditions related to Alzheimer´s disease. We will also explore the main roles of astrocytes in the pathogenesis of Alzheimer´s disease and summarize main transcriptional changes and altered molecular pathways observed in astrocytes during the course of the disease.

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“…Importantly, it was found that although the AD risk gene apolipoprotein E (APOE) was repressed in astrocyte subpopulations and in AD-related oligodendrocyte progenitor cells, it was upregulated in an AD-specific microglial subpopulations within the EC, suggesting that these specialized cells contribute to disease susceptibility of the EC during AD. A selectively vulnerable subpopulation of excitatory neurons in the EC, which shows a corresponding selective depletion as the disease progresses, has also been identified using SnRNA-seq in post-mortem AD brains ( Leng et al, 2020 , preprint). Interestingly, this study identified nuclear receptor RAR-related orphan receptor beta (RORB), which is a developmental driver of neuronal subtype identity ( Jabaudon et al, 2012 ; Oishi et al, 2016 ), as a marker for the selective vulnerability of excitatory EC neurons.…”

Section: Drivers Of Molecular Neurodegeneration and Vulnerability Of mentioning

confidence: 99%

Molecular mechanisms of neurodegeneration in the entorhinal cortex that underlie its selective vulnerability during the pathogenesis of Alzheimer's disease

2021

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The entorhinal cortex (EC) is a vital component of the medial temporal lobe, and its contributions to cognitive processes and memory formation are supported through its extensive interconnections with the hippocampal formation. During the pathogenesis of Alzheimer's disease (AD), many of the earliest degenerative changes are seen within the EC. Neurodegeneration in the EC and hippocampus during AD has been clearly linked to impairments in memory and cognitive function, and a growing body of evidence indicates that molecular and functional neurodegeneration within the EC may play a primary role in cognitive decline in the early phases of AD. Defining the mechanisms underlying molecular neurodegeneration in the EC is crucial to determining its contributions to the pathogenesis of AD. Surprisingly few studies have focused on understanding the mechanisms of molecular neurodegeneration and selective vulnerability within the EC. However, there have been advancements indicating that early dysregulation of cellular and molecular signaling pathways in the EC involve neurodegenerative cascades including oxidative stress, neuroinflammation, glia activation, stress kinases activation, and neuronal loss. Dysfunction within the EC can impact the function of the hippocampus, which relies on entorhinal inputs, and further degeneration within the hippocampus can compound this effect, leading to severe cognitive disruption. This review assesses the molecular and cellular mechanisms underlying early degeneration in the EC during AD. These mechanisms may underlie the selective vulnerability of neuronal subpopulations in this brain region to the disease development and contribute both directly and indirectly to cognitive loss.This paper has an associated Future Leader to Watch interview with the first author of the article.

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Molecular characterization of selectively vulnerable neurons in Alzheimer’s Disease

Cited by 19 publications

References 98 publications

Bayesian estimation of cell-type-specific gene expression per bulk sample with prior derived from single-cell data

Bayesian estimation of cell-type-specific gene expression per bulk sample with prior derived from single-cell data

Astrocytes in Alzheimer´s Disease: Pathological Significance and Molecular Pathways

Molecular mechanisms of neurodegeneration in the entorhinal cortex that underlie its selective vulnerability during the pathogenesis of Alzheimer's disease

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