Project description:Genetic studies have revealed an essential role for cytosine DNA methylation in gene regulation. However, its spatiotemporal distribution in the developing embryo remains obscure. Here, we profiled the DNA methylation landscape of 12 mouse tissues/organs at 8 developmental stages spanning from early embryo to birth. In-depth analysis of such spatiotemporal epigenome maps uncovered widespread regulatory DNA element dynamics during embryogenesis. We systematically delineated methylation variants that likely drive gene transcription, whose human counterparts are enriched for genetic risk factors of human diseases. Strikingly, these predicted regulatory elements predominantly lose CG methylation during fetal development, whereas the trend is reversed after birth. Key transcription factors, essential for early tissue/organ development, accumulate non-CG methylation within their gene bodies, coinciding with transcriptional repression during late stage fetal development. These spatiotemporal epigenomic datasets provide a valuable resource for studies of gene regulation during mammalian tissue/organ progression and the possible origins of human developmental diseases.

Project description:The plasma proteome is maintained by the influx and efflux of proteins from surrounding organs and cells. To quantify the impact surrounding organs and cells have on the plasma proteome, we developed a mass spectrometry-based proteomics strategy to infer the origin of proteins detected in human plasma. To quantify the extent different organs and cells contribute to the plasma proteome composition, we developed a mass spectrometry-based proteomics strategy to infer the origin of proteins detected in human plasma in healthy and diseased conditions. We constructed an extensive human proteome atlas from 18 vascularized organs and the 8 most abundant cell types in blood. The atlas was interfaced with previous RNA and protein atlases to objectively define proteome wide protein-organ associations to enable both the inference of origin and the reproducible quantification of organ-specific proteins in plasma. We demonstrate that the resource can determine disease-specific quantitative changes of organ-enriched protein panels in six separate patient cohorts including sepsis, pancreatitis, and myocardial injury. The strategy can be extended to other diseases to advance our understanding of the processes contributing to plasma proteome dynamics.

Project description:The larynx, trachea, and esophagus share origin and proximity during embryonic development, with clinical and experimental evidence supporting the existence of neurophysiological, structural, and functional interdependencies before birth. This investigation provides the first comprehensive transcriptional profiling of all three organs during embryonic organogenesis, where differential gene expression gradually assembles the identity and complexity of these proximal organs from a shared origin in the anterior foregut. Through the application of bulk RNA sequencing and gene network analysis of differentially expressed genes (DEGs), both within and across developing embryonic mouse larynx, esophagus, and trachea, we identified co-expressed modules of genes enriched for key biological processes. Organ-specific temporal patterns of gene activity corresponding to gene modules within and across shared tissues during embryonic development (E10.5-E18.5) are described, and the laryngeal transcriptome during vocal fold development and maturation from birth to adult is characterized in the context of laryngeal organogenesis. The findings of this study provide new insights into interrelated gene sets governing organogenesis of this tripartite organ system within the aerodigestive tract, with relevance to multiple families of disorders defined by cardiocraniofacial syndromes.

Project description:The endoderm is classically defined as the innermost layer of three Metazoan germ layers. During organogenesis, the endoderm gives rise to the digestive and respiratory tracts as well as associated organs such as the liver, pancreas, and lung. At present, however, how the endoderm forms the variety of cell types of digestive and respiratory tracts as well as the budding organs is not well understood. In order to investigate the molecular basis and mechanism of organogenesis and to identify the endodermal organ-related marker genes, we carried out microarray analysis using Xenopus cDNA chips. To achieve this goal, we isolated the Xenopus gut endoderm from three different stages of Xenopus organogenesis, and separated each stage of gut endoderm into anterior and posterior region. Competitive hybridization of cDNA between the anterior and posterior endoderm regions, to screen genes that specifically expressed in the major anterior organs, revealed 891 candidates. We then selected 104 clones for in situ hybridization analysis. Here, we report the identification and expression patterns of the 104 Xenopus endodermal genes, which would serve as useful markers for studying endodermal organ development. Keywords: Xenopus, endoderm, microarray, organogenesis

Project description:Background: As core units of organ tissues, cells of various types play their harmonious rhythms to maintain the homeostasis of the human body. It is essential to identify the characteristics of cells in human organs and their regulatory networks for understanding the biological mechanisms related to health and disease. However, a systematic and comprehensive single-cell transcriptional profile across multiple organs of a normal human adult is missing. Results: We perform single-cell transcriptomes of 84,363 cells derived from 15 tissue organs of one adult donor and generate an adult human cell atlas. The adult human cell atlas depicts 252 subtypes of cells, including major cell types such as T, B, myeloid, epithelial, and stromal cells, as well as novel COCH+ fibroblasts and FibSmo cells, each of which is distinguished by multiple marker genes and transcriptional profiles. These collectively contribute to the heterogeneity of major human organs. Moreover, T cell and B cell receptor repertoire comparisons and trajectory analyses reveal direct clonal sharing of T and B cells with various developmental states among different tissues. Furthermore, novel cell markers, transcription factors and ligand-receptor pairs are identified with potential functional regulations in maintaining the homeostasis of human cells among tissues. Conclusions: The adult human cell atlas reveals the inter- and intra-organ heterogeneity of cell characteristics and provides a useful resource in uncovering key events during the development of human diseases in the context of the heterogeneity of cells and organs.

Project description:During early mammalian development, the endoderm layer undergoes complex patterning to form the foundations of the respiratory and digestive systems. This intricate process, guided by a series of cell fate decisions, remains only partially understood. Our research introduces a pioneering genetic tracing code across 14 distinct endodermal regions by developing a group of mouse strains. By integrating high-throughput and high-precision single-cell RNA sequencing with sophisticated imaging techniques across various mouse models, we comprehensively resolve the spatiotemporal and genetic lineage differentiation processes of the endoderm at a single-cell resolution. Our findings reveal a previously unrecognized multipotentiality within early endodermal regions for differentiation into diverse organ primordia. Furthermore, this research illuminates the complex and underestimated phenomenon of multiple origins in the development of endodermal organs, prompting a reevaluation of differentiation models for these organs. This work not only advances our understanding of developmental biology, but also has significant implications for regenerative medicine and the development of organoid models, providing new insights into the intricate mechanisms that guide organogenesis.

Project description:During early mammalian development, the endoderm layer undergoes complex patterning to form the foundations of the respiratory and digestive systems. This intricate process, guided by a series of cell fate decisions, remains only partially understood. Our research introduces a pioneering genetic tracing code across 14 distinct endodermal regions by developing a group of mouse strains. By integrating high-throughput and high-precision single-cell RNA sequencing with sophisticated imaging techniques across various mouse models, we comprehensively resolve the spatiotemporal and genetic lineage differentiation processes of the endoderm at a single-cell resolution. Our findings reveal a previously unrecognized multipotentiality within early endodermal regions for differentiation into diverse organ primordia. Furthermore, this research illuminates the complex and underestimated phenomenon of multiple origins in the development of endodermal organs, prompting a reevaluation of differentiation models for these organs. This work not only advances our understanding of developmental biology, but also has significant implications for regenerative medicine and the development of organoid models, providing new insights into the intricate mechanisms that guide organogenesis.

Project description:During early mammalian development, the endoderm layer undergoes complex patterning to form the foundations of the respiratory and digestive systems. This intricate process, guided by a series of cell fate decisions, remains only partially understood. Our research introduces a pioneering genetic tracing code across 14 distinct endodermal regions by developing a group of mouse strains. By integrating high-throughput and high-precision single-cell RNA sequencing with sophisticated imaging techniques across various mouse models, we comprehensively resolve the spatiotemporal and genetic lineage differentiation processes of the endoderm at a single-cell resolution. Our findings reveal a previously unrecognized multipotentiality within early endodermal regions for differentiation into diverse organ primordia. Furthermore, this research illuminates the complex and underestimated phenomenon of multiple origins in the development of endodermal organs, prompting a reevaluation of differentiation models for these organs. This work not only advances our understanding of developmental biology, but also has significant implications for regenerative medicine and the development of organoid models, providing new insights into the intricate mechanisms that guide organogenesis.

Project description:The early-life organ development and maturation process shapes the fundamental blueprint for later-life phenotype. However, the proteome atlas of self-multi-organs from infancy to adulthood is currently not available. Herein, we present a comprehensive proteomic analysis of ten mice organs (brain, heart, lung, liver, kidney, spleen, stomach, intestine, muscle and skin) acquired from the same individuals at three essential developmental stages (1-week, 4-week and 8-week after birth) by data-independent acquisition mass spectrometry.

Project description:Extensive studies of the model plant Arabidopsis has enabled a deep understanding of organs and tissues throughout plant development. Yet, a fundamental understanding of cell types and states across organs and development is still lacking. Here, we present a single-nucleus transcriptome atlas of Arabidopsis seed-to-seed development encompassing diverse tissues across ten developmental time points. Analysis of over 400,000 nuclei revealed 183 major and 653 subclusters that demarcate cell type and state. Cross-organ analyses revealed that the transcriptional identity of many cell types is conserved across development but influenced by the organ of origin and developmental timing. In addition, groups of transcription factors were enriched and uniquely expressed in individual organs and time points, suggesting developmental gatekeeping of transcription factor activation. Finally, we employed spatial transcriptomics to validate our findings in the highly complex silique organ.