Project description:The small intestinal crypt exhibits a defined spatial organisation involving multiple cell types that undergo continuous proliferation and differentiation while migrating towards the villus. We have built a multi-scale agent-based model (ABM), with individual cells interacting in the crypt geometry, which reproduces the self-organizing stable behaviour reported for the crypt. In our ABM, spatial organization emerges from the dynamic interaction of multiple signalling pathways, which include the Wnt, Notch, BMP and RNF43/ZNRF3 pathways that orchestrate cellular fate and mechanisms of contact inhibition of proliferation as well as feedback loops that regulate the expansion of the niche and size of the crypt. Moreover, this dynamic signalling network interacts with the main cell cycle proteins, governing the progression of each cell across the division stages.

Project description:Multiple distinct cell types of the human lung and airways have been defined by single cell RNA sequencing (scRNAseq). Here we present a multi-omics spatial lung atlas to define novel cell types which we map back into the macro- and micro-anatomical tissue context to define functional tissue microenvironments. Firstly, we have generated single cell and nuclei RNA sequencing, VDJ-sequencing and Visium Spatial Transcriptomics data sets from 5 different locations of the human lung and airways. Secondly, we define additional cell types/states, as well as spatially map novel and known human airway cell types, such as adult lung chondrocytes, submucosal gland (SMG) duct cells, distinct pericyte and smooth muscle subtypes, immune-recruiting fibroblasts, peribronchial and perichondrial fibroblasts, peripheral nerve associated fibroblasts and Schwann cells. Finally, we define a survival niche for IgA-secreting plasma cells at the SMG, comprising the newly defined epithelial SMG-Duct cells, and B and T lineage immune cells. Using our transcriptomic data for cell-cell interaction analysis, we propose a signalling circuit that establishes and supports this niche. Overall, we provide a transcriptional and spatial lung atlas with multiple novel cell types that allows for the study of specific tissue microenvironments such as the newly defined gland-associated lymphoid niche (GALN).

Project description:The hematopoietic stem cell (HSC) niche has been extensively studied in bone marrow, yet a more systematic investigation into the microenvironment regulation of hematopoiesis in fetal liver is necessary. Here we investigate the spatial organization and transcriptional profile of individual cells in both wild type and Tet2-/- fetal livers, by multiplexed error robust fluorescence in situ hybridization (MERFISH). We find that specific pairs of fetal liver cell types are preferentially positioned next to each other. Ligand-receptor singling molecule pairs such as Kitl and Kit are enriched in neighboring cell types. The majority of HSCs are directly in contact with endothelial cells (ECs) in both wild type and Tet2-/- fetal livers. Loss of Tet2 increases the number of HSCs, and upregulates Wnt and Notch signaling genes in the HSC niche. Two subtypes of ECs – arterial ECs and sinusoidal ECs – and other cell types contribute distinct signaling molecules to the HSC niche. Collectively, this study provides a comprehensive picture and bioinformatic foundation for HSC spatial regulation in fetal liver.

Project description:The hematopoietic stem cell (HSC) niche has been extensively studied in bone marrow, yet a more systematic investigation into the microenvironment regulation of hematopoiesis in fetal liver is necessary. Here we investigate the spatial organization and transcriptional profile of individual cells in both wild type and Tet2-/- fetal livers, by multiplexed error robust fluorescence in situ hybridization (MERFISH). We find that specific pairs of fetal liver cell types are preferentially positioned next to each other. Ligand-receptor singling molecule pairs such as Kitl and Kit are enriched in neighboring cell types. The majority of HSCs are directly in contact with endothelial cells (ECs) in both wild type and Tet2-/- fetal livers. Loss of Tet2 increases the number of HSCs, and upregulates Wnt and Notch signaling genes in the HSC niche. Two subtypes of ECs – arterial ECs and sinusoidal ECs – and other cell types contribute distinct signaling molecules to the HSC niche. Collectively, this study provides a comprehensive picture and bioinformatic foundation for HSC spatial regulation in fetal liver.

Project description:B cell-interacting reticular cells (BRC) form transcriptionally and topologically stable immune-interacting microenvironments that direct efficient humoral immunity. While several immune niche factors have been elucidated, the cues sustaining BRC function and topology across activation states remain unclear. Here, we employed spatial transcriptome analysis of murine ingunal and mesenteric lymph nodes to examine co-localization of distinct BRC subsets and immune cells complementing BRC-immune cell interaction analysis. Spatial analysis supported predicted feedforward BRC-immune cell circuits that sustain topologically-organized, functional niches across inflammatory states, lymphoid organs and species.

Project description:Single-cell RNA-sequencing of murine small intestinal organoid cultured with and without lymphatic endothelial cells: Purpose: To identify differences in cell composition in murine organoids upon coculture with lymphatic endothelial cells Results: We recovered 818 cells with a median of 37750 UMIs per cell for the organoid alone and 1233 cells with a median of 79354 UMIs per cells for the cocultured organoid condition. Conclusions: scRNASeq reveals different cell composition in organoids cocultured with lymphatic endothelial cells compared to control Single-cell RNA-Sequencing of murine small and large intestinal tissue: Purpose: To generate a reference dataset of all major cell types present in the small and large intestine of the mouse Results: For the small intestine we recovered 8842 cells with a median of 4088 UMIs per cell compared to 8646 cells with a median of 10009 UMIs per cell for the large intestine. Conclusions: scRNASeq recovers all of the major epithelial, immune and stromal cell types in the intestine. Spatial transcriptomic profiling of murine small and large intestine: Purpose: To spatially map the major cell types in the mouse intestine and infer cell:cell communication from neighboring cells Conclusions: Spatial transcriptomic profiling of the mouse small and large intestine reveals all major cell types and allows for cell:cell signaling analyses upon integration with our matching scRNA-Seq data

Project description:The application of single-cell RNA sequencing (scRNAseq) to the bone field has led to significant advancements in our understanding of skeletal stem cell (SSC) heterogeneity, yet disparity remains in the characterization of these cells in the context of their native environment. To resolve these limitations, we combined scRNAseq and spatial transcriptomics in adult femurs to provide endogenous, in vivo context. First, predictive modeling was used to determine the spatial location of SSCs within the bone marrow. These results localized CXCL12-abundant reticular cells to the bone marrow, while PDGFRα+SCA1+ were found to enrich within the outer periosteum. Correlative analyses were next used to define the cellular niche composition, identifying smooth muscle cells, as well as endothelial cell and macrophage subtypes overrepresented within the SSC niche. Using cell-cell communication prediction and spatial transcriptomics, we defined ligand-receptor pairs specifically expressed within the niche and mapped their expression back to niche-resident cells. Finally, these SSC niches were placed in the context of bone microdomains. Signaling gradients derived from the vasculature and bone surfaces were unbiasedly assessed using SpatialTime. This data indicated a striking, spatially-restricted activation of metabolic and major morphogenetic pathways. This project demonstrates the ability of this technique to spatially localize SSC subpopulations, define the cellular components of the stem cell niche, unravel cell-cell communication and place this niche in the context of its bone microdomain to gain a comprehensive understanding of local and global SSC regulatory networks within the bone.

Project description:As Sox17 plays a critical role in the development of multiple cell types during early embryogenesis, we utilized a dual-color lineage-tracing strategy in combination with single-cell RNA sequencing (scRNAseq) to capture and analyze Sox17-expressing lineages. GFP production from Sox17GFPCre allele marks cells that currently express Sox17 or short-term progeny of Sox17 expressing progenitors. TdTomato production from R26LSL.TdTomato reporter allele in the presence of Sox17GFPCre marks long-term progeny of Sox17-expressing progenitors. In brief, GFP and Tdtomato positive cells were isolated from E9.5 embryos of specific genotypes to generate two separate scRNAseq datasets, referred to in the manuscript as the GFP and TdTomato datasets, respectively.

Project description:Cellular function is strongly dependent on surrounding cells and environmental factors. Current technologies are limited in characterizing the spatial location and unique gene-programs of cells in less structured and dynamic niches. Here we developed a method (NICHE-seq) that combines photoactivatable fluorescent reporters, two-photon microscopy and single-cell RNA-seq to infer the cellular and molecular composition of niches. We applied NICHE-seq to examine the high-order assembly of immune cell networks. NICHE-seq is highly reproducible in spatial tissue reconstruction, enabling identification of rare niche-specific immune subpopulations and unique gene-programs, including natural killer cells within infected B cell follicles and distinct myeloid states in the marginal zone. This study establishes NICHE-seq as a broadly applicable method for elucidating high-order spatial organization of cell types and their molecular pathways.

Project description:The control of host processes which influence cell-cell communication is central to determining the outcome of a virus infection in tissue. Despite this, it remains unclear how cells either in close or distant proximity to an infected cell differentially respond to the primary infection. Here, we established a virus infection microenvironment to resolve molecular features and functional consequences of cell spatial address within this localized niche by mass spectrometry. To rule out the possibility that neighboring cells are infected by the viral progeny from the primary infection, cidofovir is added in the system to prevent viral genome replication in order to prevent the spread of infection.