Project description:FOHM data share

Project description:Framingham SHARe Social Network

Project description:We developed an optimized, low-cost, split-pool barcoding-based multimodal profiling protocol based upon SHARE-seq (concurrent single-cell ATAC/RNA-seq). With SHARE-seq, we profiled human kidney samples from multiple different anatomical regions. Therefore, we develop a large-scale multimodal single-cell atlas for 3D anatomy of the human kidney.

Project description:SHARe Asthma Resource Project (SHARP)

Project description:Single-cell multiome sequencing of human kidney anatomical regions with SHARE-seq

Project description:SHARE-seqV2 for single-cell epigenomic and transcriptomic mapping of human hematopoiesis at scale

Project description:Discovery of interaction sites between RNA-binding proteins (RBPs) and their RNA targets plays a critical role in enabling our understanding of how these RBPs control RNA processing and regulation. Cross-linking and immunoprecipitation (CLIP) provides a generalizable, transcriptome-wide method by which RBP:RNA complexes are purified and sequenced to identify sites of intermolecular contact. By simplifying technical challenges in prior CLIP methods and incorporating the generation of and quantitative comparison against size-matched input controls, the single-end enhanced CLIP (seCLIP) protocol allows for the profiling of these interactions with high resolution, efficiency, and scalability.

Project description:Approved drugs are invaluable tools to study biochemical pathways and further characterization of these compounds may lead to repurposing of single drugs or combinations. Here, we describe a collection of 308 small molecules representing the diversity of structures and molecular targets of all FDA-approved chemical entities. The CeMM Library of Unique Drugs (CLOUD) covers prodrugs and active forms at pharmacologically relevant concentrations and is ideally suited for combinatorial studies. We screened pairwise combinations of CLOUD drugs for impairment of cancer cell viability and discovered the synergistic interaction between flutamide and phenprocoumon (PPC). The combination of these two drugs modulates the stability of the androgen receptor (AR) and resensitizes AR mutant prostate cancer cells to flutamide. Mechanistically, we show that the AR is a substrate for γ-carboxylation, a post-translational modification inhibited by PPC. Collectively, our data suggest that PPC might be repurposed to tackle resistance to antiandrogens in prostate cancer patients.

Project description:Cis-regulatory elements (CREs) are bound by diverse chromatin-associated proteins, cooperate to establish gene expression, and change in structure over time to alter cell fate and function1–3. Here, we develop a footprinting framework that uses deep learning to correct Tn5 sequence bias, improving accuracy and reducing false positives. This framework additionally identifies the interaction of DNA with objects of various sizes. Using these ‘multi-scale footprints’ we find that transcription factor (TF) binding occurs at well-defined distances from nucleosomes. Further, we demonstrate that multi-scale footprints, which include the positions of nucleosomes, enable more accurate inference of TF binding. Using multi-scale footprinting with single-cell multi-omics, we discover wide-spread structural and functional changes of CREs across hematopoiesis, wherein nucleosomes slide, expose DNA for TF binding, and promote gene expression. Finally, we apply this single-cell and footprint approach to characterize age-associated structural changes to CREs within hematopoietic stem cells and identify a spectrum of cells harboring age-associated changes to the epigenome. Interestingly, we find extensive changes to the structure of CREs upon aging, with many age-associated changes altering CRE structure while preserving overall accessibility. Collectively, we reveal the dynamics and functional importance of CRE structure, highlighting changes to gene regulation at single-cell and single-base-pair resolution.

Project description:Simultaneous measurement of different molecular aspects of gene regulation can help infer functional relationships between genome regulation and gene expression, and understand their distinct and contribution to cell phenotype. Here, we present SHARE-seq, a highly scalable, sensitive, and cost-effective approach for joint measurement of chromatin accessibility and gene expression from the same single cells. Applying SHARE-seq to adult mouse tissues (skin, brain, lung) we show a direct congruence in cell type definition by either chromatin accessibility or RNA expression and create cell-type specific regulatory maps. We leverage naturally occurring cell-cell variation to infer chromatin-expression regulatory relationships and develop a broadly applicable computational strategy to define cis- ad trans- regulatory programs. The cis-regulatory programs, which largely overlap with super-enhancers, are found at key lineage-specifying genes. We demonstrate dynamic chromatin evidence of both gene expression lineage-priming and lineage-memory. The combined scalability and depth of SHARE-seq provide an extensible platform to study the regulatory relationships governing chromatin and gene expression changes across diverse cells within tissues.