Single-nucleus RNA-seq identifies Huntington disease astrocyte states

Single-nucleus RNA-seq identifies Huntington disease astrocyte states

Huntington Disease (HD) is an inherited movement disorder caused by expanded CAG repeats in the Huntingtin gene. We have used single nucleus RNASeq (snRNASeq) to uncover cellular phenotypes that change in the disease, investigating single cell gene expression in cingulate cortex of patients with HD...

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Bibliographic Details
Published in:Acta neuropathologica communications Vol. 8; no. 1; p. 19
Main Authors: Al-Dalahmah, Osama, Sosunov, Alexander A, Shaik, A, Ofori, Kenneth, Liu, Yang, Vonsattel, Jean Paul, Adorjan, Istvan, Menon, Vilas, Goldman, James E
Format: Journal Article
Language:English
Published: England BioMed Central 18-02-2020
BMC
Subjects:
Adult
Aged
Astrocytes
Astrocytes - metabolism
Cingulate cortex
Clustering
Female
Gene Expression
Genomics
Gyrus Cinguli - metabolism
Humans
Huntington disease
Huntington Disease - genetics
Huntington Disease - metabolism
Huntingtons disease
Male
Middle Aged
Pathology
Proteins
Sequence Analysis, RNA
Single-Cell Analysis
Single-cell RNA-sequencing
Single-cell RNA-sequencing
Cingulate cortex
Gene expression
Astrocytes
Huntington disease
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Summary:Huntington Disease (HD) is an inherited movement disorder caused by expanded CAG repeats in the Huntingtin gene. We have used single nucleus RNASeq (snRNASeq) to uncover cellular phenotypes that change in the disease, investigating single cell gene expression in cingulate cortex of patients with HD and comparing the gene expression to that of patients with no neurological disease. In this study, we focused on astrocytes, although we found significant gene expression differences in neurons, oligodendrocytes, and microglia as well. In particular, the gene expression profiles of astrocytes in HD showed multiple signatures, varying in phenotype from cells that had markedly upregulated metallothionein and heat shock genes, but had not completely lost the expression of genes associated with normal protoplasmic astrocytes, to astrocytes that had substantially upregulated glial fibrillary acidic protein (GFAP) and had lost expression of many normal protoplasmic astrocyte genes as well as metallothionein genes. When compared to astrocytes in control samples, astrocyte signatures in HD also showed downregulated expression of a number of genes, including several associated with protoplasmic astrocyte function and lipid synthesis. Thus, HD astrocytes appeared in variable transcriptional phenotypes, and could be divided into several different "states", defined by patterns of gene expression. Ultimately, this study begins to fill the knowledge gap of single cell gene expression in HD and provide a more detailed understanding of the variation in changes in gene expression during astrocyte "reactions" to the disease.
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ISSN:2051-5960
2051-5960
DOI:10.1186/s40478-020-0880-6