Project description:Spatial transcriptomics map of the embryonic mouse brain: a tool to explore neurogenesis

Project description:Single-cell RNAseq (scRNAseq) and paired VDJ analysis and spatial transcriptomics, we create the first comprehensive cell atlas of the healthy developing, paediatric and adult human gut, including 347,980 cells from up to 10 distinct anatomical sites. We use this data to trace the cellular composition of the gut throughout life, define novel cell markers and cell-cell interactions. We find four neuronal cell populations in the developing enteric nervous system, with expression patterns indicative of irritable bowel syndrome and Hirschsprung’s disease, and identify key cell players and communication networks initiating lymphoid structure formation in early human development.

Project description:Spatial organization of different cell types within prenatal skin across various anatomical sites is not well understood. To address this, here we have generated spatial transcriptomics data from prenatal facial and abdominal skin obtained from a donor at 10 post conception weeks. This in combination with our prenatal skin scRNA-seq dataset has helped us map the location of various identified cell types.

Project description:Spatial transcriptomics analysis of adult hippocampal neurogenesis in the human brain

Project description:We report a spatial transcriptomics dataset of mouse brain tissue generated with the 10x Genomics Visium platform to identify gene expression profiles of spatial object recognition training.

Project description:The process of cardiac morphogenesis in humans is incompletely understood. Its full characterization requires a deep exploration of the organ-wide orchestration of gene expression with a single-cell spatial resolution. Here, we present a molecular approach that reveals the comprehensive transcriptional landscape of cell types populating the embryonic heart at three developmental stages, and which maps cell type-specific gene expression to specific anatomical domains. Spatial Transcriptomics identified unique gene profiles corresponding to distinct anatomical regions in each developmental stage. Human embryonic cardiac cell types identified by single-cell RNA-sequencing confirmed and enriched the spatial annotation of embryonic cardiac gene expression. In situ sequencing was then used to refine these results and create spatial subcellular map for the three developmental phases. Finally, we generated a publicly available web resource of the human developing heart to facilitate future studies on human cardiogenesis.

Project description:Mammalian embryos exhibits sophisticated cell organizations that are intricately orchestrated at both molecular and cellular level. It has recently become apparent that cells within the animal body display significant heterogeneity, both in terms of their cellular properties and their spatial distributions. However, current spatial transcriptomics profiling either lack three-dimensional representation or are limited in their ability to capture the complexity of embryonic tissues and organs. Here, we present a represented spatial transcriptome atlas of all major organs at embryonic day 13.5 (E13.5) in the mouse embryo, and provide a three- dimensional rendering of molecular regulation for embryonic patterning with stacked sections. By integrating this spatial transcriptome data with corresponding single-cell transcriptome data, we offer a detailed molecular annotation of the dynamic nature of organ development, spatial cellular interaction, embryonic axes and divergence of cell fates underlying mammalian development, which would pave the way for precise organ engineering and stem cell-based regenerative medicine.

Project description:Purpose:To gain a deeper insight into how TCF20 regulates neurogenesis in mice brain, RNA-sequencing (RNA-seq) was performed to analyze the genome-wide changes by TCF20 deletion at E13.5. Methods: Total RNA was extracted from E13.5 telencephalic tissue of TCF20 WT HET KO mice. Then total RNA was quality controlled and quantified using an Agilent 2100 Bioanalyzer. After converting to cDNA and building library, high-throughput sequencing was performed using the Illumina HiSeq 2500 platform in Annoroad Genomics. Results: Approximately approximately one thousand transcripts showed differential expression between the WT and TCF20 KO brain cortex, with a fold change ≥1.5 and p value <0.05. Gene ontology (GO) analysis showed that the down-regulated genes were enriched in the terms related to neurogenesis, neuronal specification, neural differentiation and secretion by cells. Up-regulated genes showed a significant enrichment of terms involved in up regulation of hypersensitivity and up regulation of inflammatory response. These results reflected the importance of TCF20 in cortical neurogenesis. Conclusions: We conclude that RNA-seq based transcriptome characterization would provide a framework for understanding how TCF20 gene contribute to brain cortical development.

Project description:We report a spatial transcriptomics dataset of mouse brain tissue generated with the 10x Genomics Visium platform to identify gene expression changes after sleep deprivation

Project description:Spatial omics are increasingly "fused" with classical biomedical imaging modalities to complement them with spatially-resolved molecular profiling, enabling deeper understanding of the biochemical basis of health and diesease. Before the multimodal information can be fused, all contributing imaging data must be spatially aligned through a process called coregistration, which remains a challenge. Here we present a multimodal coregistration framework with great genericity and accuracy for spatial omics data. Specifically, an original dimension reduction algorithm "PseudoRep" is used to bridge cross-modal gaps: PseudoRep can generate a single-channel representation of the highly multiplexed molecular image from spatial omics and ensure that the resulting representation appears "pseudo-unimodal" to the image from the other modality. Then, a Deep Learning-based transformation algorithm "DeepReg" is adopted to accurately model nonlinear tissue deformations due to anatomical variations or sample manipulations. Our method demonstrated its versatility by coregistering mass spectrometry imaging-mediated spatial metabolomics data with diverse modalities (magnetic resonance imaging, brain atlas, microscopy, and spatial transcriptomics) and reduced 38\%\textemdash69\% of coregistration errors compared to existing methods. Notably, we open-source a toolbox to implement both the coregistration and its downstream tasks (co-expression analysis, anatomical annotation, and pansharpening), which is expected to greatly facilitate the democratization of multimodal fusion studies in the spatial omics community.