A gene regulatory network directed by zebrafish No tail accounts for its roles in mesoderm formation

Morley, Rosalind H.; Lachani, Kim; Keefe, Damian; Gilchrist, Michael J.; Flicek, Paul; Smith, James C.; Wardle, Fiona C.

doi:10.1073/pnas.0808382106

Cited by 108 publications

(126 citation statements)

References 52 publications

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“…As expected, skeletal muscle development (Myog) was compromised in the E10.0∼10.5 Tc/Tc embryos (Fig. 4D), consistent with its reported regulatory function in zebrafish (13).…”

Section: Brachyury Coordinates Gene Expression During In Vitro Streaksupporting

confidence: 72%

“…Here, we systematically characterized the molecular function of Brachyury during ES cell differentiation by genomic, single-cell imaging, and biochemical approaches. We then contrasted our results with published zebrafish and Xenopus Brachyury binding site mapping data (12,13) to compare evolutionarily convergent or divergent pathways. We further extended these studies to examine the direct impact of Brachyury loss of function during early development with the Tc mouse model.…”

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confidence: 91%

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Charting Brachyury-mediated developmental pathways during early mouse embryogenesis

Lolas

Valenzuela

Tjian

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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To gain insights into coordinated lineage-specification and morphogenetic processes during early embryogenesis, here we report a systematic identification of transcriptional programs mediated by a key developmental regulator-Brachyury. High-resolution chromosomal localization mapping of Brachyury by ChIP sequencing and ChIP-exonuclease revealed distinct sequence signatures enriched in Brachyury-bound enhancers. A combination of genomewide in vitro and in vivo perturbation analysis and cross-species evolutionary comparison unveiled a detailed Brachyury-dependent gene-regulatory network that directly links the function of Brachyury to diverse developmental pathways and cellular housekeeping programs. We also show that Brachyury functions primarily as a transcriptional activator genome-wide and that an unexpected gene-regulatory feedback loop consisting of Brachyury, Foxa2, and Sox17 directs proper stem-cell lineage commitment during streak formation. Target gene and mRNA-sequencing correlation analysis of the T c mouse model supports a crucial role of Brachyury in up-regulating multiple key hematopoietic and musclefate regulators. Our results thus chart a comprehensive map of the Brachyury-mediated gene-regulatory network and how it influences in vivo developmental homeostasis and coordination.primitive streak | early development | mesoendoderm differentiation I n the past decade, significant insights have been gained in understanding gene-regulatory programs responsible for embryonic stem (ES) cell pluripotency and self-renewal. However, transcriptional control mechanisms underlying finely balanced lineage-segregation and morphogenetic processes during early mammalian embryogenesis remained elusive. During early mouse gastrulation, Brachyury (T), a classical enhancer-binding transcription factor (TF), has been reported to be required for the proper development of primitive streak, allantois, axial, and posterior mesoderm (reviewed in ref. 1).Specifically, mouse embryos that are homozygous for the Brachyury (T) deletion die at midgestation (2). T −/− mutant epiblast cells are compromised in their ability to migrate away from the primitive streak and, therefore, are unable to undergo the morphogenetic movements carried out by their wild-type (WT) counterparts during gastrulation. In addition to defects in the primitive streak, the notochord is absent in posterior portions of the embryo. Although the anterior portions of T mutant mice contain notochordal precursor-like cells, they fail to undergo normal terminal differentiation (3, 4). The embryonic pattern posterior to the forelimb region of T −/− animals is also disturbed, with somites posterior to the seventh pair absent or abnormal. Although neural folds fuse to form the neural tube, they are severely kinked in the caudal region, and the surface ectoderm tends to form fluid-filled blisters (2, 4, 5). In addition to these well-documented defects, numerous other phenotypic abnormalities have been reported in T −/− and T mutant embryos, including left-right pattern...

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“…As expected, skeletal muscle development (Myog) was compromised in the E10.0∼10.5 Tc/Tc embryos (Fig. 4D), consistent with its reported regulatory function in zebrafish (13).…”

Section: Brachyury Coordinates Gene Expression During In Vitro Streaksupporting

confidence: 72%

mentioning

confidence: 91%

Charting Brachyury-mediated developmental pathways during early mouse embryogenesis

Lolas

Valenzuela

Tjian

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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show abstract

“…These transcriptional changes result from a pre-determined differentiation program and regulate differentiation. Within the embryo, coordination of transcription in specific blastomeres requires intricate gene regulatory networks (Levine and Davidson, 2005;Chan et al, 2009;Morley et al, 2009). tion of cytosines within CpG dinucleotides is generally associated with gene repression, notably during development and differentiation (Jaenisch and Bird, 2003).…”

Section: Introductionmentioning

confidence: 99%

Chromatin states of developmentally-regulated genes revealed by DNA and histone methylation patterns in zebrafish embryos

Lindeman¹,

Winata²,

Aanes³

et al. 2010

Int. J. Dev. Biol.

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Embryo development proceeds from a cascade of gene activation and repression events controlled by epigenetic modifications of DNA and histones. Little is known about epigenetic states in the developing zebrafish, despite its importance as a model organism. We report here DNA methylation and histone modification profiles of promoters of developmentallyregulated genes (pou5f1, sox2, sox3, klf4, nnr, otx1b, nes, vasa), as well as tert and bactin2, in zebrafish embryos at the mid-late blastula transition, shortly after embryonic genome activation. We identify four classes of promoters based on the following profiles: (i) those enriched in marks of active genes (H3K9ac, H4ac, H3K4me3) without transcriptionally repressing H3K9me3 or H3K27me3; (ii) those enriched in H3K9ac, H4ac and H3K27me3, without H3K9me3; one such gene was klf4, shown by in situ hybridization to be mosaically expressed, likely accounting for the detection of both activating and repressive marks on its promoter; (iii) those enriched in H3K4me3 and H3K27me3 without acetylation; and (iv) those enriched in all histone modifications examined. Culture of embryo-derived cells under differentiation conditions leads to H3K9 and H4 deacetylation and H3K9 and H3K27 trimethylation on genes that are inactivated, yielding an epigenetic profile similar to those of fibroblasts or muscle. All promoters however retain H3K4me3, indicating an uncoupling of H3K4me3 occupancy and gene expression. All non-CpG island developmentallyregulated promoters are DNA unmethylated in embryos, but hypermethylated in fibroblasts. Our results suggest that differentially expressed embryonic genes are regulated by various patterns of histone modifications on unmethylated DNA, which create a developmentally permissive chromatin state.

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“…Morley et al [74] combined immunoprecipitation and microarray data to identify targets of No tail, a zebrafish ortholog that plays a central role in mesoderm formation. Using genome-scale data, they assembled a preliminary gene regulatory network that begins to describe mesoderm formation and patterning in the zebrafish embryo.…”

Section: Network Inference or Reverse Engineeringmentioning

confidence: 99%

Systems biology: Leading the revolution in ecotoxicology

García-Reyero

Perkins

2010

Enviro Toxic and Chemistry

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Abstract-The rapid development of new technologies such as transcriptomics, proteomics, and metabolomics (Omics) are changing the way ecotoxicology is practiced. The data deluge has begun with genomes of over 65 different aquatic species that are currently being sequenced, and many times that number with at least some level of transcriptome sequencing. Integrating these top-down methodologies is an essential task in the field of systems biology. Systems biology is a biology-based interdisciplinary field that focuses on complex interactions in biological systems, with the intent to model and discover emergent properties of the system. Recent studies demonstrate that Omics technologies provide valuable insight into ecotoxicity, both in laboratory exposures with model organisms and with animals exposed in the field. However, these approaches require a context of the whole animal and population to be relevant. Powerful approaches using reverse engineering to determine interacting networks of genes, proteins, or biochemical reactions are uncovering unique responses to toxicants. Modeling efforts in aquatic animals are evolving to interrelate the interacting networks of a system and the flow of information linking these elements. Just as is happening in medicine, systems biology approaches that allow the integration of many different scales of interaction and information are already driving a revolution in understanding the impacts of pollutants on aquatic systems. Environ. Toxicol. Chem. 2011;30:265-273. # 2010 SETAC

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A gene regulatory network directed by zebrafish No tail accounts for its roles in mesoderm formation

Cited by 108 publications

References 52 publications

Charting Brachyury-mediated developmental pathways during early mouse embryogenesis

Charting Brachyury-mediated developmental pathways during early mouse embryogenesis

Chromatin states of developmentally-regulated genes revealed by DNA and histone methylation patterns in zebrafish embryos

Systems biology: Leading the revolution in ecotoxicology

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