Project description:Understanding the molecular processes underlying intra-tumor heterogeneity is of critical importance to improve the efficiency of therapy and overcome drug resistance. In malignant melanoma, heterogeneity is though to arise -at least partly- through epigenetic rather than genetic reprogramming of proliferating cells, leading to the appearance within the primary tumors of a phenotypically distinct invasive cell subpopulation. The invasive melanoma cells are at the origin of metastatic spread and are thought to provide a reservoir of therapeutically resistant cells. To decipher the gene regulatory networks that underlie the proliferative and invasive cellular states we integrated publicly available gene expression and DNA methylation data from tumor biopsies with a newly generated compendium of open chromatin and histone modification profiling of melanoma cultures that are dominant in either of the two subpopulations. Extensive in silico analyses identified SOX10 and MITF, and AP-1 and TEADs as key upstream regulators of the proliferative and invasive transcriptomes, respectively. Knock-down experiments confirmed the implication of TEADs in the invasive gene network and, more importantly, established a causative link between activation of these transcription factors and melanoma cell invasion and sensitivity to MAPK inhibitors.

Project description:Understanding the molecular processes underlying intra-tumor heterogeneity is of critical importance to improve the efficiency of therapy and overcome drug resistance. In malignant melanoma, heterogeneity is though to arise -at least partly- through epigenetic rather than genetic reprogramming of proliferating cells, leading to the appearance within the primary tumors of a phenotypically distinct invasive cell subpopulation. The invasive melanoma cells are at the origin of metastatic spread and are thought to provide a reservoir of therapeutically resistant cells. To decipher the gene regulatory networks that underlie the proliferative and invasive cellular states we integrated publicly available gene expression and DNA methylation data from tumor biopsies with a newly generated compendium of open chromatin and histone modification profiling of melanoma cultures that are dominant in either of the two subpopulations. Extensive in silico analyses identified SOX10 and MITF, and AP-1 and TEADs as key upstream regulators of the proliferative and invasive transcriptomes, respectively. Knock-down experiments confirmed the implication of TEADs in the invasive gene network and, more importantly, established a causative link between activation of these transcription factors and melanoma cell invasion and sensitivity to MAPK inhibitors.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Understanding the molecular processes underlying intra-tumor heterogeneity is of critical importance to improve the efficiency of therapy and overcome drug resistance. In malignant melanoma, heterogeneity is though to arise -at least partly- through epigenetic rather than genetic reprogramming of proliferating cells, leading to the appearance within the primary tumors of a phenotypically distinct invasive cell subpopulation. The invasive melanoma cells are at the origin of metastatic spread and are thought to provide a reservoir of therapeutically resistant cells. To decipher the gene regulatory networks that underlie the proliferative and invasive cellular states we integrated publicly available gene expression and DNA methylation data from tumor biopsies with a newly generated compendium of open chromatin and histone modification profiling of melanoma cultures that are dominant in either of the two subpopulations. Extensive in silico analyses identified SOX10 and MITF, and AP-1 and TEADs as key upstream regulators of the proliferative and invasive transcriptomes, respectively. Knock-down experiments confirmed the implication of TEADs in the invasive gene network and, more importantly, established a causative link between activation of these transcription factors and melanoma cell invasion and sensitivity to MAPK inhibitors.

Project description:Somatic embryogenesis is a unique process in plants and has considerable interest for biotechnological application. Compare to japonica, indica rice has been less responsive to in vitro culture. We used Illumina Hiseq 2000 sequencing platform for comparative transcriptome analysis between two rice subspecies at six different developmental stages combined with a tag-based digital gene expression profiling. Global gene expression among different samples showed greater complexity in japonica rice compared to indica which may be due to polyphyletic origin of two rice subspecies. Expression pattern in initial stage indicate major differences in proembryogenic callus induction phase that may serve as key regulator to observe differences between both subspecies. Our data suggests that phytohormone signaling pathways consist of elaborate networks with frequent crosstalk, thereby allowing plants to regulate somatic embryogenesis pathway. However, this crosstalk varies between the two rice subspecies. Down regulation of positive regulators of meristem development (i.e. KNOX, OsARF5) and up regulation of its counterparts (OsRRs, MYB, GA20ox1/GA3ox2) in japonica may be responsible for its better regeneration and differentiation of somatic embryos. Comprehensive gene expression information in the present experiment may also facilitate to understand the monocot specific meristem regulation for dedifferentiation of somatic cell to embryogenic cells.

Project description:BackgroundRegulatory T cells (Tregs) expressing the transcription factor FOXP3 are crucial mediators of self-tolerance, preventing autoimmune diseases but possibly hampering tumor rejection. Clinical manipulation of Tregs is of great interest, and first-in-man trials of Treg transfer have achieved promising outcomes. Yet, the mechanisms governing induced Treg (iTreg) differentiation and the regulation of FOXP3 are incompletely understood.ResultsTo gain a comprehensive and unbiased molecular understanding of FOXP3 induction, we performed time-series RNA sequencing (RNA-Seq) and proteomics profiling on the same samples during human iTreg differentiation. To enable the broad analysis of universal FOXP3-inducing pathways, we used five differentiation protocols in parallel. Integrative analysis of the transcriptome and proteome confirmed involvement of specific molecular processes, as well as overlap of a novel iTreg subnetwork with known Treg regulators and autoimmunity-associated genes. Importantly, we propose 37 novel molecules putatively involved in iTreg differentiation. Their relevance was validated by a targeted shRNA screen confirming a functional role in FOXP3 induction, discriminant analyses classifying iTregs accordingly, and comparable expression in an independent novel iTreg RNA-Seq dataset.ConclusionThe data generated by this novel approach facilitates understanding of the molecular mechanisms underlying iTreg generation as well as of the concomitant changes in the transcriptome and proteome. Our results provide a reference map exploitable for future discovery of markers and drug candidates governing control of Tregs, which has important implications for the treatment of cancer, autoimmune, and inflammatory diseases.

Project description:Extensive epigenetic reprogramming occurs during preimplantation embryo development. However, it remains largely unclear how the drastic epigenetic reprogramming contributes to transcriptional regulatory network during this period. Here, we develop a single-cell multiomics sequencing technology (scNOMeRe-seq) that enables profiling of genome-wide chromatin accessibility, DNA methylation and RNA expression in the same individual cell. We apply this method to depict a single-cell multiomics map of mouse preimplantation development. We find that genome-wide DNA methylation remodeling facilitates the reconstruction of genetic lineages in early embryos. Further, we construct a zygotic genome activation (ZGA)-associated regulatory network and reveal coordination among multiple epigenetic layers, transcription factors and repeat elements that instruct proper ZGA. Cell fates associated cis-regulatory elements are activated stepwise in post-ZGA stages. Trophectoderm (TE)-specific transcription factors play dual roles in promoting the TE program while repressing the inner cell mass (ICM) program during the ICM/TE separation.

Project description:Technological improvements enable single-cell epigenetic analyses of organ development. We reasoned that high-resolution single-cell chromatin accessibility mapping would provide needed insight into the epigenetic reprogramming and transcriptional regulators involved in normal mammary gland development. Here, we provide a single-cell resource of chromatin accessibility for murine mammary development from the peak of fetal mammary stem cell (fMaSC) functional activity in late embryogenesis to the differentiation of adult basal and luminal cells. We find that the chromatin landscape within individual cells predicts both gene accessibility and transcription factor activity. The ability of single-cell chromatin profiling to separate E18 fetal mammary cells into clusters exhibiting basal-like and luminal-like chromatin features is noteworthy. Such distinctions were not evident in analyses of droplet-based single-cell transcriptomic data. We present a web application as a scientific resource for facilitating future analyses of the gene regulatory networks involved in mammary development.

Project description:CD4+ T regulatory cells (Treg) are central to immune homeostasis, their phenotypic heterogeneity reflecting the diverse environments and target cells that they regulate. To understand this heterogeneity, we combined single-cell RNA-seq, activation reporter and T cell receptor (TCR) analysis to profile thousands of Treg or conventional CD4+FoxP3- T cells (Tconv) from mouse lymphoid organs and human blood. Treg and Tconv pools showed areas of overlap, as resting 'furtive' Tregs with overall similarity to Tconvs or as a convergence of activated states. All Tregs expressed a small core of FoxP3-dependent transcripts, onto which additional programs were added less uniformly. Among suppressive functions, Il2ra and Ctla4 were quasiconstant, inhibitory cytokines being more sparsely distributed. TCR signal intensity did not affect resting/activated Treg proportions but molded activated Treg programs. The main lines of Treg heterogeneity in mice were strikingly conserved in human blood. These results reveal unexpected TCR-shaped states of activation, providing a framework to synthesize previous observations of Treg heterogeneity.

Project description:The large collections of ChIP-seq data rapidly accumulating in public data warehouses provide genome-wide binding site maps for hundreds of transcription factors (TFs). However, the extent of the regulatory occupancy space in the human genome has not yet been fully apprehended by integrating public ChIP-seq data sets and combining it with ENCODE TFs map. To enable genome-wide identification of regulatory elements we have collected, analysed and retained 395 available ChIP-seq data sets merged with ENCODE peaks covering a total of 237 TFs. This enhanced repertoire complements and refines current genome-wide occupancy maps by increasing the human genome regulatory search space by 14% compared to ENCODE alone, and also increases the complexity of the regulatory dictionary. As a direct application we used this unified binding repertoire to annotate variant enhancer loci (VELs) from H3K4me1 mark in two cancer cell lines (MCF-7, CRC) and observed enrichments of specific TFs involved in biological key functions to cancer development and proliferation. Those enrichments of TFs within VELs provide a direct annotation of non-coding regions detected in cancer genomes. Finally, full access to this catalogue is available online together with the TFs enrichment analysis tool (http://tagc.univ-mrs.fr/remap/).