Project description:Cell-specific transcriptional regulatory networks (TRNs) play vital roles in plant development and response to environmental stresses. However, traditional single-cell mono-omics techniques are unable to fully capture the relationships and dynamics of molecular information within cells. While data integration algorithm facilitates the merging of single-cell RNA-seq and single-cell ATAC-seq data, ensuring the accuracy of the integration process remains a challenge, particularly when investigating cell-type-specific TRNs. In this study, we aimed to elucidate the TRNs of Arabidopsis under osmotic stress at the single-cell level by employing single-cell multi-omics technology to simultaneously examine gene expression and chromatin accessibility of 16,670 Arabidopsis root tip nuclei. We performed 12,968 peak-to-gene linkage at bona fide single-cell level, instead of previous computational integration at cell type level, which enabled us to obtain an unprecedented resolution to reconstruct transcriptional regulation. Pseudotime developmental trajectories revealed that osmotic stress led to shift the developmental status of Suberin synthetic endodermis (Suberin-endo) and trichoblast cells. We identified candidate stress-related cell-specific enhancers and cis-regulatory elements as well as potential target genes, and uncovered large cellular heterogeneity. We also found that cis-regulatory elements became accessible prior to gene expression and these cis-regulatory elements could form a positive feedback loop with epigenetic modification H3K4me3 in response to osmotic stress in columella cells.

Project description:Cell-specific transcriptional regulatory networks (TRNs) play vital roles in plant development and response to environmental stresses. However, traditional single-cell mono-omics techniques are unable to fully capture the relationships and dynamics of molecular information within cells. While data integration algorithm facilitates the merging of single-cell RNA-seq and single-cell ATAC-seq data, ensuring the accuracy of the integration process remains a challenge, particularly when investigating cell-type-specific TRNs. In this study, we aimed to elucidate the TRNs of Arabidopsis under osmotic stress at the single-cell level by employing single-cell multi-omics technology to simultaneously examine gene expression and chromatin accessibility of 16,670 Arabidopsis root tip nuclei. We performed 12,968 peak-to-gene linkage at bona fide single-cell level, instead of previous computational integration at cell type level, which enabled us to obtain an unprecedented resolution to reconstruct transcriptional regulation. Pseudotime developmental trajectories revealed that osmotic stress led to shift the developmental status of Suberin synthetic endodermis (Suberin-endo) and trichoblast cells. We identified candidate stress-related cell-specific enhancers and cis-regulatory elements as well as potential target genes, and uncovered large cellular heterogeneity. We also found that cis-regulatory elements became accessible prior to gene expression and these cis-regulatory elements could form a positive feedback loop with epigenetic modification H3K4me3 in response to osmotic stress in columella cells.

Project description:SWATH analysis of Yeast Proteome over time in response to Osmotic Stress. We sampled cell cultures in biological triplicates at six time points following the application of osmotic stress and acquired single injection DIA datasets on a high-resolution 5600 tripleTOF instrument operated in SWATH mode. Proteins were quantified by the targeted extraction and signal integration from the SWATH-MS datasets of peak groups representing proteotypic peptides for specific yeast proteins.

Project description:SWATH analysis of Yeast Proteome over time in response to Osmotic Stress. We sampled cell cultures in biological triplicates at six time points following the application of osmotic stress and acquired single injection DIA datasets on a high-resolution 5600 tripleTOF instrument operated in SWATH mode. Proteins were quantified by the targeted extraction and signal integration from the SWATH-MS datasets of peak groups representing proteotypic peptides for specific yeast proteins.

Project description:Saccharomyces cerevisiae cells have evolved remarkably sophisticated and flexible transcriptional regulatory networks (TRNs) that allow them to survive and thrive in stress conditions, such as high temperature, osmotic and oxidative conditions, etc. Furthermore, transcription factor plays a central role in transcriptional regulatory networks of stress response. To achieve a thorough understanding of master transcription factors and transcriptional regulatory networks in specific response to prolonged thermal stress, we sequenced mRNA from the cultures of the wild type strain ScY01a as well as four key transcription factor deletion strains including ScY01a (ric1∆), ScY01a (srb2∆), ScY01a (sin3∆) and ScY01a (mig1∆) grown at 40ºC in biological duplicates. Differences in gene expression comparing the transcription factor deletion strains with the wild type strain by RNA deep sequencing revealed a hierarchical transcriptional regulatory network required for long-term thermal stress tolerance of S. cerevisiae, which is centered on these four transcription factors.

Project description:Saccharomyces cerevisiae cells have evolved remarkably sophisticated and flexible transcriptional regulatory networks (TRNs) that allow them to survive and thrive in stress conditions, such as high temperature, osmotic and oxidative conditions, etc. Furthermore, transcription factor plays a central role in transcriptional regulatory networks of stress response. To achieve a thorough understanding of master transcription factors and transcriptional regulatory networks in specific response to prolonged thermal stress, we previously sequenced mRNA from the cultures of the wild type strain ScY01a as well as three key transcription factor deletion strains including ScY01a (srb2∆), ScY01a (sin3∆) and ScY01a (mig1∆) grown at 40ºC in biological duplicates. Here, we further sequenced the corresponding samples cultured at 30ºC as a control. Differences in gene expression comparing the transcription factor deletion strains with the wild type strain by RNA deep sequencing revealed a hierarchical transcriptional regulatory network centered on these three transcription factors in S. cerevisiae.

Project description:Cis-regulatory elements (CREs) encode the genomic blueprints for coordinating the spatiotemporal regulation of gene transcription programs necessary for highly specialized cellular functions. To identify cis-regulatory elements underlying cell-type specification and developmental transitions, we implemented single-cell sequencing of Assay for Transposase Accessible Chromatin (scATAC-seq) in an atlas of Zea mays tissues and organs. We describe 92 distinct patterns of chromatin accessibility across more than 165,913 putative CREs, greater than 56,575 cells, and 52 known cell-types using a novel regularized quasibinomial logistic model for estimating single cell accessibility. Cell-type specification could be largely explained by combinatorial accessibility of transcription factors (TFs) and their associated binding. Analysis of cell type-specific co-accessible chromatin recapitulated higher-order chromatin interactions, providing novel insight into cell type-specific regulatory dynamics. Integration of genetic diversity data revealed cell-type specific CREs contributed to specific morphological and molecular phenotypic traits indicative of their cellular functions, expanding our understanding of the molecular influence of complex traits in a eukaryotic species. 

Project description:Cells require coordinated control over gene expression changes when responding to environmental stimuli. Recent advancements in single-cell technologies have enabled studies of regulatory dynamics associated with cellular perturbation response in immune cells. However, associating these changes to underlying differences in epigenetic regulation through integration of multi-omic data has not been achieved at single-cell resolution. Here, we apply single-cell ATAC-seq (scATAC-seq) and scRNA-seq to assay chromatin accessibility and gene expression in resting and stimulated human blood cells. Collectively, we generate ~91,000 high-coverage single-cell profiles, allowing us to probe the cis-regulatory landscape of immunological response across cell types, stimuli and time. Advancing tools to integrate multiomic data, we connect distal cis-regulatory elements to genes, identifying key regulatory hubs associated with immune signaling and stress response. Subsequently, we design FigR - a method to infer gene regulatory networks (GRNs) to identify candidate TF regulators across single cells. Importantly, construction of a GRN using stimulus response data identifies TF regulatory activity associated with  genetic variants in inflammatory diseases. Lastly, we assess the time-dependent regulatory dynamics of immune stimulation, where we find that cells alter chromatin accessibility prior to productive gene expression, a process occurring at time scales of minutes. Extending this concept of chromatin-mediated priming, and incorporating regulatory relationships defined by FigR, we detect a rare subpopulation of monocytes marked by a primed chromatin state predictive of enhanced immunological response. Overall, we build upon computational tools for GRN construction and demonstrate the utility of GRNs for analysis of multi-omic single cell data.

Project description:Cells require coordinated control over gene expression changes when responding to environmental stimuli. Recent advancements in single-cell technologies have enabled studies of regulatory dynamics associated with cellular perturbation response in immune cells. However, associating these changes to underlying differences in epigenetic regulation through integration of multi-omic data has not been achieved at single-cell resolution. Here, we apply single-cell ATAC-seq (scATAC-seq) and scRNA-seq to assay chromatin accessibility and gene expression in resting and stimulated human blood cells. Collectively, we generate ~91,000 high-coverage single-cell profiles, allowing us to probe the cis-regulatory landscape of immunological response across cell types, stimuli and time. Advancing tools to integrate multiomic data, we connect distal cis-regulatory elements to genes, identifying key regulatory hubs associated with immune signaling and stress response. Subsequently, we design FigR - a method to infer gene regulatory networks (GRNs) to identify candidate TF regulators across single cells. Importantly, construction of a GRN using stimulus response data identifies TF regulatory activity associated with  genetic variants in inflammatory diseases. Lastly, we assess the time-dependent regulatory dynamics of immune stimulation, where we find that cells alter chromatin accessibility prior to productive gene expression, a process occurring at time scales of minutes. Extending this concept of chromatin-mediated priming, and incorporating regulatory relationships defined by FigR, we detect a rare subpopulation of monocytes marked by a primed chromatin state predictive of enhanced immunological response. Overall, we build upon computational tools for GRN construction and demonstrate the utility of GRNs for analysis of multi-omic single cell data.

Project description:Cells require coordinated control over gene expression changes when responding to environmental stimuli. Recent advancements in single-cell technologies have enabled studies of regulatory dynamics associated with cellular perturbation response in immune cells. However, associating these changes to underlying differences in epigenetic regulation through integration of multi-omic data has not been achieved at single-cell resolution. Here, we apply single-cell ATAC-seq (scATAC-seq) and scRNA-seq to assay chromatin accessibility and gene expression in resting and stimulated human blood cells. Collectively, we generate ~91,000 high-coverage single-cell profiles, allowing us to probe the cis-regulatory landscape of immunological response across cell types, stimuli and time. Advancing tools to integrate multiomic data, we connect distal cis-regulatory elements to genes, identifying key regulatory hubs associated with immune signaling and stress response. Subsequently, we design FigR - a method to infer gene regulatory networks (GRNs) to identify candidate TF regulators across single cells. Importantly, construction of a GRN using stimulus response data identifies TF regulatory activity associated with  genetic variants in inflammatory diseases. Lastly, we assess the time-dependent regulatory dynamics of immune stimulation, where we find that cells alter chromatin accessibility prior to productive gene expression, a process occurring at time scales of minutes. Extending this concept of chromatin-mediated priming, and incorporating regulatory relationships defined by FigR, we detect a rare subpopulation of monocytes marked by a primed chromatin state predictive of enhanced immunological response. Overall, we build upon computational tools for GRN construction and demonstrate the utility of GRNs for analysis of multi-omic single cell data.