Single-nucleus RNA-seq of differentiating human myoblasts reveals the extent of fate heterogeneity

Zeng, Weihua; Jiang, Shan; Kong, Xiangduo; El-Ali, Nicole; Ball, Alexander R.; I-Hsing, Christopher; Hashimoto, Naohiro; Yokomori, Kyoko; Mortazavi, A

doi:10.1093/nar/gkw739

Cited by 77 publications

(99 citation statements)

References 81 publications

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“…We used two independent primary control myoblast samples, Control-1 and Control-2, and two independent primary FSHD2 myoblast samples, FSHD2-1 and FSHD2-2, which have known SMCHD1 mutations. In addition, we compared our time-course to the differentiation of the immortalized human myoblast cell line KD3 [23] which was used previously to study the fate heterogeneity during myotube differentiation by single-nucleus RNA-seq [21]. After sequencing two biological replicate RNA samples for each of the five cell populations every day for six days, we filtered out lowly expressed genes across all 60 samples and performed principal component analysis (PCA) with 10,767 genes ( Figure 1B).…”

Section: Upregulation Of Fshd-induced Genes During Fshd2 Myotube Diffmentioning

confidence: 99%

“…We found that about 40% of differentially expressed genes are known FSHD-associated genes while the others may be potential new candidates involved in the progression of the disease. We then used single-cell RNA-seq in myoblasts and single-nucleus RNA-seq [21] in 3-day postdifferentiation myotubes to characterize the expression patterns of DUX4 and other FSHDinduced genes. We sucessfully detected the first set of single nuclei with DUX4 expression (DUX4-detected) from FSHD myotubes and found that they do not express all the FSHDinduced genes whereas a much larger set of FSHD myotube nuclei express FSHD-induced genes.…”

Section: Introductionmentioning

confidence: 99%

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Single-nucleus RNA-seq identifies divergent populations of FSHD2 myotube nuclei

Jiang

Williams

Kong

et al. 2018

Preprint

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AbstractFSHD is characterized by the misexpression of DUX4 in skeletal muscle. However, DUX4 is lowly expressed in patient samples and analysis of the consequences of DUX4 expression has largely relied on artificial overexpression. To better understand the native expression profile of DUX4 and its targets, we performed pooled RNA-seq differentiation time-course in FSHD2 patient-derived primary myoblasts and identified early-and late-induced sets of FSHD-associated genes. Using single-cell and single-nucleus RNA-seq on FSHD2 myoblasts and myotubes respectively, we captured DUX4 expression in single-nuclei and found that only some DUX4 targets are coexpressed. We identified two populations of FSHD myotube nuclei with distinct transcriptional profiles. One population is highly enriched with DUX4 and FSHD related genes, including the DUX4 paralog DUXA (“FSHD-Hi”). The other population has no expression of DUX4 and expresses low amounts of FSHD related genes (“FSHD-Lo”), but is marked by the expression of CYTL1 and CHI3L1. “FSHD-Hi” myotube nuclei upregulated a set of transcription factors (TFs) that may form a self-sustaining network of gene dysregulation, which perpetuates this disease after DUX4 is no longer expressed.

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Section: Upregulation Of Fshd-induced Genes During Fshd2 Myotube Diffmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Single-nucleus RNA-seq identifies divergent populations of FSHD2 myotube nuclei

Jiang

Williams

Kong

et al. 2018

Preprint

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“…Thus, existing high-throughput single-cell capture and library preparation methods, including isolation of cells by fluorescence activated cell sorting (FACS) into multi-well plates, sub-nanoliter wells, or droplet microfluidic encapsulation, are not optimized to accommodate these unusually large cells. Isolating individual nuclei for transcriptome analysis is a promising strategy, as single-nucleus RNA-Seq methods avoid strong biases against cells of complex morphology and large size (Habib et al, 2016; Lacar et al, 2016; Lake et al, 2016; Zeng et al, 2016) and can be potentially standardized to accommodate the study of various tissues. However, current single-nucleus RNA-Seq methods primarily rely on fluorescence-activated nuclei sorting (FANS) (Habib et al, 2016; Lake et al, 2016) or Fluidigm C1 microfludics platform (Zeng et al, 2016) to capture nuclei, and thus cannot easily be scaled up to generate a comprehensive atlas of cell types in a given tissue, much less a whole organism.…”

Section: Introductionmentioning

confidence: 99%

Dissecting Cell-Type Composition and Activity-Dependent Transcriptional State in Mammalian Brains by Massively Parallel Single-Nucleus RNA-Seq

et al. 2017

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SUMMARY Massively parallel single-cell RNA sequencing can precisely resolve cellular diversity in a high-throughput manner at low cost, but unbiased isolation of intact single cells from complex tissues, such as adult mammalian brains, is challenging. Here, we integrate sucrose-gradient assisted purification of nuclei with droplet microfluidics to develop a highly scalable single-nucleus RNA-Seq approach (sNucDrop-Seq), which is free of enzymatic dissociation and nuclei sorting. By profiling ~18,000 nuclei isolated from cortical tissues of adult mice, we demonstrate that sNucDrop-Seq not only accurately reveals neuronal and non-neuronal subtype composition with high sensitivity, but also enables in-depth analysis of transient transcriptional states driven by neuronal activity, at single-cell resolution, in vivo.

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“…Recently, profiling the transcriptome of individual cells has emerged as a powerful strategy for resolving such heterogeneity. The expression levels of mRNA species are linked to cellular function, and therefore can be used to classify cell types (2–10) and to order cell states (11). Although methods for single cell RNA-seq have proliferated, they rely on the isolation of individual cells within physical compartments (12–20).…”

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confidence: 99%

Comprehensive single-cell transcriptional profiling of a multicellular organism

Cao

Packer

Ramani

et al. 2017

Science

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To resolve cellular heterogeneity, we developed a combinatorial indexing strategy to profile the transcriptomes of single cells or nuclei (sci-RNA-seq: Single cell Combinatorial Indexing RNA sequencing). We applied sci-RNA-seq to profile nearly 50,000 cells from the nematode Caenorhabditis elegans at the L2 stage, which is over 50-fold “shotgun cellular coverage” of its somatic cell composition. From these data, we define consensus expression profiles for 27 cell types, and recover rare neuronal cell types corresponding to as few as one or two cells in the L2 worm. We integrate these profiles with whole animal ChIP sequencing data to deconvolve the cell type specific effects of transcription factors. These data generated by sci-RNA-seq constitute a powerful resource for nematode biology, and foreshadow similar atlases for other organisms.

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Single-nucleus RNA-seq of differentiating human myoblasts reveals the extent of fate heterogeneity

Cited by 77 publications

References 81 publications

Single-nucleus RNA-seq identifies divergent populations of FSHD2 myotube nuclei

Single-nucleus RNA-seq identifies divergent populations of FSHD2 myotube nuclei

Dissecting Cell-Type Composition and Activity-Dependent Transcriptional State in Mammalian Brains by Massively Parallel Single-Nucleus RNA-Seq

Comprehensive single-cell transcriptional profiling of a multicellular organism

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