Project description:Single-cell transcriptomics reveals early emergence of liver parenchymal and non-parenchymal cell lineages

Project description:Embryonic development involves a range of complex morphogenic events as the embryo generates various cell types that go onto form functional tissues. This process is heavily reliant on symmetry breaking events that control the emergence of separate lineages that then spatial organize and physically arranging themselves within the embryo often via regulation of cell-cell adhesions. This work examines how changing adhesions in 3D aggregates of human pluripotent stem cells (hPSCs) encapsulated in hydrogel mixed with extracellular matrix allows for emergent population and morphological behaviors reminiscent of early embryonic behaviors and morphologies. In this context, knockdown of the cell adhesion molecule CDH1 generated aggregates with protrusion morphologies that did not arise in aggregates cultured without encapsulation. Genomic analysis revealed that the combination of CDH1 knockdown and encapsulation promoted emergence of extra-embryonic lineages. Further the transcriptomes of encapsulated CDH1(-) hPSCs were comparable to previously published single cell RNA-sequencing data of human embryos. Overall, these results establish a hPSC culture system that resembles early embryonic fate decisions and morphologies. Additionally, these studies highlight a potential relationship between changing adhesions, microenvironment, and acquisition of specific lineage fates, progressing our understanding of early human embryonic biology.

Project description:Adult-derived human liver stem/progenitor cells (ADHLSC) are obtained after primary culture of the liver parenchymal fraction. The cells are of fibroblastic morphology and exhibit a hepato-mesenchymal phenotype. Hepatic stellate cells (HSC) derived from the liver non-parenchymal fraction present a comparable morphology as ADHLSC. Because both ADHLSC and HSC are described as liver stem/progenitor cells, we strived to extensively compare both cell populations at different levels and to propose tools demonstrating their singularity. The database include full expression (HGU-219) measurements samples from 7 Adult-Derived Human Liver Stem/progenitor (n=7) and human hepatic stellate samples (n=7)

Project description:The human liver functions through a complex interplay of parenchymal and non-parenchymal cells, which participate in performing many essential aspects of metabolism and secretion. Mass spectrometry-based proteomic analysis of intact tissue has improved the understanding of these processes, by providing an in-depth view of the human liver proteome. However, the predominance of parenchymal cells, i.e. hepatocytes, means that the total tissue proteome mainly reflects hepatocyte expression. In this study, we therefore used quantitative label-free proteomic analysis to analyze the proteomes of the major parenchymal and non-parenchymal cell types in the human liver, i.e. hepatocytes, liver sinusoidal endothelial cells, Kupffer cells, and hepatic stellate cells. We found that our data recapitulated specific functional differences between cell types, meaning that it can be used to reliably probe various aspects of cellular interplay. Thus, the data we provide constitutes a unique resource for exploring the human liver proteome at major cell type resolution.

Project description:Adult-derived human liver stem/progenitor cells (ADHLSC) are obtained after primary culture of the liver parenchymal fraction. The cells are of fibroblastic morphology and exhibit a hepato-mesenchymal phenotype. Hepatic stellate cells (HSC) derived from the liver non-parenchymal fraction present a comparable morphology as ADHLSC. Because both ADHLSC and HSC are described as liver stem/progenitor cells, we strived to extensively compare both cell populations at different levels and to propose tools demonstrating their singularity.

Project description:Liver fibrosis is a major cause of death worldwide. As a progressive step in chronic liver disease, fibrosis is almost always diagnosed too late with limited treatment options. Here, we uncover the spatial transcriptional landscape driving human liver fibrosis using single nuclei RNA and Assay for Transposase-Accessible Chromatin (ATAC) sequencing to deconvolute multi-cell spatial transcriptomic profiling in human liver cirrhosis.Through multi-modal data integration,we define molecular signatures driving cell state transitions in liver disease and define an impaired cellular response and directional trajectory from hepatocytes to cholangiocytes associated with disease remodelling.We identifypro-fibrogenic signatures in non-parenchymal cell subpopulations co-localised within the fibrotic niche and localise transitional cell states at the scar interface. This combined approach providesa spatial atlas of gene regulation and defines molecular signatures associated liver diseasefor targeted therapeutics or as early diagnostic markers of progressive liver disease. This is the 10X Visium data for the work.

Project description:Liver fibrosis is a major cause of death worldwide. As a progressive step in chronic liver disease, fibrosis is almost always diagnosed too late with limited treatment options. Here, we uncover the spatial transcriptional landscape driving human liver fibrosis using single nuclei RNA and Assay for Transposase-Accessible Chromatin (ATAC) sequencing to deconvolute multi-cell spatial transcriptomic profiling in human liver cirrhosis.Through multi-modal data integration,we define molecular signatures driving cell state transitions in liver disease and define an impaired cellular response and directional trajectory from hepatocytes to cholangiocytes associated with disease remodelling.We identifypro-fibrogenic signatures in non-parenchymal cell subpopulations co-localised within the fibrotic niche and localise transitional cell states at the scar interface. This combined approach providesa spatial atlas of gene regulation and defines molecular signatures associated liver diseasefor targeted therapeutics or as early diagnostic markers of progressive liver disease. This is the snRNA-seq data for the work.

Project description:Liver fibrosis is a major cause of death worldwide. As a progressive step in chronic liver disease, fibrosis is almost always diagnosed too late with limited treatment options. Here, we uncover the spatial transcriptional landscape driving human liver fibrosis using single nuclei RNA and Assay for Transposase-Accessible Chromatin (ATAC) sequencing to deconvolute multi-cell spatial transcriptomic profiling in human liver cirrhosis.Through multi-modal data integration,we define molecular signatures driving cell state transitions in liver disease and define an impaired cellular response and directional trajectory from hepatocytes to cholangiocytes associated with disease remodelling.We identifypro-fibrogenic signatures in non-parenchymal cell subpopulations co-localised within the fibrotic niche and localise transitional cell states at the scar interface. This combined approach providesa spatial atlas of gene regulation and defines molecular signatures associated liver diseasefor targeted therapeutics or as early diagnostic markers of progressive liver disease. This is the snATAC-seq data for the work.

Project description:Liver fibrosis is a major cause of death worldwide. As a progressive step in chronic liver disease, fibrosis is almost always diagnosed too late with limited treatment options. Here, we uncover the spatial transcriptional landscape driving human liver fibrosis using single nuclei RNA and Assay for Transposase-Accessible Chromatin (ATAC) sequencing to deconvolute multi-cell spatial transcriptomic profiling in human liver cirrhosis.Through multi-modal data integration,we define molecular signatures driving cell state transitions in liver disease and define an impaired cellular response and directional trajectory from hepatocytes to cholangiocytes associated with disease remodelling.We identifypro-fibrogenic signatures in non-parenchymal cell subpopulations co-localised within the fibrotic niche and localise transitional cell states at the scar interface. This combined approach providesa spatial atlas of gene regulation and defines molecular signatures associated liver diseasefor targeted therapeutics or as early diagnostic markers of progressive liver disease. This is the 10X Visium data for the work.

Project description:We applied single-cell RNAseq analysis to characterize hepatic cell types, including hepatocytes (Hep) and non-parenchymal cells (NPC), in mouse liver, during Myc-induced hepatocellular carcinoma (HCC) development.