Project description:The functional heterogeneity of β-cells is important for metabolism and diseases, but the nature and mechanism of such variation at molecular level remain elusive. Here we explore this question by comparing both single cell RNA-seq and single cell ATAC-seq maps of healthy and type II diabetic (T2D) human islets. We dissect the T2D-associated single cell trajectory and identified signature genes and enhancers in β-cells. We also map the 3D genome of both α- and β-cells with low-input eHi-C approach to unravel the cell type-specific gene regulatory circuits. Strikingly, more than one third of the T2D signature genes show significant intra-donor heterogeneity at single cell level; these genes are functionally distinct from other signature genes that are largely invariant among cells from the same individual but differentially expressed between donors, suggesting different roles in T2D pathogenesis. Importantly, we identified consistent intra-donor variations at both transcriptomic and epigenomic levels, which strongly support the heterogenous β-cell states and transcription programs. Finally, we construct the disease-signature regulatory networks and pinpointed HNF1A as one of the top transcription factors governing T2D-associated β-cell heterogeneity. Taken together, we provide the first multi-omic characterization of β-cell heterogeneity and reveals its connection to T2D.

Project description:The functional heterogeneity of β-cells is important for metabolism and diseases, but the nature and mechanism of such variation at molecular level remain elusive. Here we explore this question by comparing both single cell RNA-seq and single cell ATAC-seq maps of healthy and type II diabetic (T2D) human islets. We dissect the T2D-associated single cell trajectory and identified signature genes and enhancers in β-cells. We also map the 3D genome of both α- and β-cells with low-input eHi-C approach to unravel the cell type-specific gene regulatory circuits. Strikingly, more than one third of the T2D signature genes show significant intra-donor heterogeneity at single cell level; these genes are functionally distinct from other signature genes that are largely invariant among cells from the same individual but differentially expressed between donors, suggesting different roles in T2D pathogenesis. Importantly, we identified consistent intra-donor variations at both transcriptomic and epigenomic levels, which strongly support the heterogenous β-cell states and transcription programs. Finally, we construct the disease-signature regulatory networks and pinpointed HNF1A as one of the top transcription factors governing T2D-associated β-cell heterogeneity. Taken together, we provide the first multi-omic characterization of β-cell heterogeneity and reveals its connection to T2D.

Project description:The functional heterogeneity of β-cells is important for metabolism and diseases, but the nature and mechanism of such variation at molecular level remain elusive. Here we explore this question by comparing both single cell RNA-seq and single cell ATAC-seq maps of healthy and type II diabetic (T2D) human islets. We dissect the T2D-associated single cell trajectory and identified signature genes and enhancers in β-cells. We also map the 3D genome of both α- and β-cells with low-input eHi-C approach to unravel the cell type-specific gene regulatory circuits. Strikingly, more than one third of the T2D signature genes show significant intra-donor heterogeneity at single cell level; these genes are functionally distinct from other signature genes that are largely invariant among cells from the same individual but differentially expressed between donors, suggesting different roles in T2D pathogenesis. Importantly, we identified consistent intra-donor variations at both transcriptomic and epigenomic levels, which strongly support the heterogenous β-cell states and transcription programs. Finally, we construct the disease-signature regulatory networks and pinpointed HNF1A as one of the top transcription factors governing T2D-associated β-cell heterogeneity. Taken together, we provide the first multi-omic characterization of β-cell heterogeneity and reveals its connection to T2D.

Project description:Here we characterize an association between disease progression and DNA methylation in Diffuse Large B cell Lymphoma (DLBCL). By profiling genome-wide DNA methylation at single base-pair resolution in thirteen DLBCL diagnosis-relapse sample pairs, we show DLBCL patients exhibit heterogeneous evolution of tumor methylomes during relapse. We identify differentially methylated regulatory elements and determine a relapse–associated methylation signature converging on key pathways such as transforming growth factor beta (TGF-beta) receptor activity. We also observe decreased intra-tumor methylation heterogeneity from diagnosis to relapsed tumor samples. Relapse-free patients display lower intra-tumor methylation heterogeneity at diagnosis compared to relapsed patients in an independent validation cohort. Furthermore, intra-tumor methylation heterogeneity is predictive of time to relapse. Therefore, we propose that epigenomic heterogeneity may support or drive the relapse phenotype and can be used to predict DLBCL relapse. Using ERRBS, we profiled genome-wide DNA methylation patterns of non-relapse DLBCL tumor samples at diagnosis, relaspe DLBCL patient samples at diagnosis and relaspe.

Project description:Inflammation is a key component of the pathogenesis of obesity-associated type 2 diabetes (T2D). However, the nature of T2D-associated islet inflammation and its impacts on T2D-associated beta cell abnormalities remain poorly defined. Using both diet-induced and genetically modified T2D animal models, we explore immune components of islet inflammation and define their roles in regulating beta cell function and proliferation. Our studies show that T2D-associated islet inflammation is uniquely dominated by macrophages, without the involvement of adaptive immune cells. We identify two islet macrophage populations, characterized by their distinct phenotypes, anatomical distributions and functional properties. Obesity induces a local expansion of intra-islet macrophages, independent of the replenishment from circulating monocytes. In contrast, the abundance of peri-islet macrophages is negligibly affected by obesity. Functionally, intra-islet macrophages impair beta cell function in a cell-cell contact dependent manner. In contrast, both intra- and peri-islet macrophage populations are able to promote beta cell proliferation. Together, these data provide a definitive view of the genesis of T2D-associated islet inflammation and define specific roles of islet macrophages in regulating beta cell function and proliferation.

Project description:Here we characterize an association between disease progression and DNA methylation in Diffuse Large B cell Lymphoma (DLBCL). By profiling genome-wide DNA methylation at single base-pair resolution in thirteen DLBCL diagnosis-relapse sample pairs, we show DLBCL patients exhibit heterogeneous evolution of tumor methylomes during relapse. We identify differentially methylated regulatory elements and determine a relapse–associated methylation signature converging on key pathways such as transforming growth factor beta (TGF-beta) receptor activity. We also observe decreased intra-tumor methylation heterogeneity from diagnosis to relapsed tumor samples. Relapse-free patients display lower intra-tumor methylation heterogeneity at diagnosis compared to relapsed patients in an independent validation cohort. Furthermore, intra-tumor methylation heterogeneity is predictive of time to relapse. Therefore, we propose that epigenomic heterogeneity may support or drive the relapse phenotype and can be used to predict DLBCL relapse.

Project description:Pancreatic endocrine cells orchestrate the precise control of blood glucose levels, but the contribution of each cell type to diabetes or obesity remains elusive. Here we used a massively parallel single-cell RNA-seq technology (Drop-Seq) to analyze the transcriptome of 26,677 pancreatic islets cells from both healthy and type II diabetic (T2D) donors. We have analyzed cell type-specific gene signatures, and detected several rare α or β cell subpopulations with high sensitivity. We also developed RePACT, a sensitive single cell analysis algorithm to identify genes associated with rare disease causing cells, or to capture the subtle disease-relevant cellular variation. We successfully identified both common and specific signature genes of obesity and T2D with only a small number of islet samples. We also performed an unbiased genome-wide CRISPR screen and mapped these Drop-Seq signature genes to the core insulin regulatory network in β cells. Notably, our integrative analysis discovered a β cell-specific function of the cohesin loading complex in regulating insulin gene transcription, and a previously unrecognized role of the NuA4/Tip60 histone acetyltransferase complex in regulating insulin release. These data demonstrated that single-cell trancriptomics is necessary to dissect the heterogeneity, disease state, and functionality of islet β cells and other cell types.

Project description:Pancreatic islet (dys)function is central to glucose homeostasis and type 2 diabetes (patho)physiology. Human islets consist of multiple endocrine (alpha, beta, delta, gamma), endothelial, and resident/inflitrating immune cells whose coordinated functions modulate glucose mobilization or disposal. Single cell transcriptome profiling (scRNA-seq) studies have been applied to dissect human islet cellular heterogeneity, identify islet cell (sub)populations, and define their molecular repertoire. However, precise understanding of cell type-specific alterations in type 2 diabetic vs. non-diabetic individuals is lacking, due in part to the limited number of individuals or single cell transcriptomes per individual profiled for comparison. Here, we create a comprehensive single cell transcriptome atlas of 245,878 human islet cells from 48 individuals spanning non-diabetic (ND), pre-diabetic (PD), and type 2 diabetic (T2D) states and matched for sex, age, and ancestry and define marker gene sets that are robustly expressed across disease states for each of the 14 cell types identified. We observe significant decreases in the number of beta cells sampled from T2D vs. ND or PD donors. Two of eight putative beta cell subpopulations, with ‘high functioning’ and ‘senescent’ cell gene signatures, increase and decrease in T2D donor islets, respectively. Importantly, we identify 511 differentially expressed genes in beta cells from T2D vs. ND donors. This includes monogenic and type 2 diabetes effector genes, such as HNF1A, DGKB, ST6GAL1, and FXYD2, for which genetic and environmental effects on their expression is concordant.  Human beta cell and islet knockdown of selected newly-identified down-regulated genes impairs beta cell viability or function. Together, this study provides new and robust, cell type-resolved insights on the cellular and molecular changes in healthy vs. diabetic human islets and represents a valuable resource to the islet biology and type 2 diabetes communities.

Project description:Type 2 Diabetes (T2D) patients have higher proportions of senescent beta-cells than their non-diabetic counterparts (Aguayo-Mazzucato et al., 2019). Senescent beta-cells may propagate dysfunction in neighboring cells through the paracrine effects of the senescence-associated secretory phenotype (SASP). To address the heterogeneity in beta-cell SASP expression and its role in T2D, we measured expression levels of beta-cell SASP signature genes in a mouse model of acute insulin resistance using the insulin receptor antagonist, S961. We have previously shown that this model induces hyperglycemia and accelerates beta-cell senescence (Aguayo-Mazzucato et al., 2019). Pancreatic islets were isolated from 3 groups of mice: a control group, a treated group of mice with surgically installed osmotic pumps secreting S961 for 2 weeks, and a third group in which mice recovered from S961 treatment for two weeks. During treatment, mice developed marked hyperglycemia and hyperinsulinemia which was completely reversed during the two-week recovery period. Islets were dispersed into single cells and scRNASeq was performed using the 10x Genomics Chromium Single Cell Gene Expression Assay.

Project description:Pancreatic islet beta cell heterogeneity has been identified, which plays a pivotal role in the pathological alterations of pancreatic islets in type 2 diabetes (T2D) mice. However, pathological alterations of beta cells in type 2 diabetes (T2D) mice remain to be investigated. We isolated pancreatic islets from the control and T2D mice and conducted scRNA-seq analysis using the 10x Genomics platform. Pathological alterations of beta cells in T2D were also explored.