An interacting network of T-box genes directs gene expression and fate in the zebrafish mesoderm

Goering, Lisa M.; Hoshijima, Kazuyuki; Hug, Barbara; Bisgrove, Brent W.; Kispert, Andreas; Grunwald, David J.

doi:10.1073/pnas.1633548100

Cited by 76 publications

(95 citation statements)

References 55 publications

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“…1B). At least 11 of these genes have been previously reported to be downregulated in ntl mutant embryos (8,(12)(13)(14)(15)(16)(17)(18)(19)(20)(21) and we highlight below several other genes whose expression is genetically regulated by Ntl.…”

Section: Ntl Binds Mesodermally Expressed Genes Involved In Transcripmentioning

confidence: 86%

“…S1 C and CЈ; Table S6). msgn1 and myod expression fail to initiate in ntl mutant embryos, although expression levels recover during gastrulation or somi- togenesis, respectively (15,21). Regulation of these myogenic factors provides a mechanism by which Ntl can influence muscle cell fate in the posterior of the embryo in addition to a general posterior identity.…”

Section: Ntl Binds Mesodermally Expressed Genes Involved In Transcripmentioning

confidence: 99%

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

Morley

Lachani

Keefe

et al. 2009

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

109

118

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Using chromatin immunoprecipitation combined with genomic microarrays we have identified targets of No tail (Ntl), a zebrafish Brachyury ortholog that plays a central role in mesoderm formation. We show that Ntl regulates a downstream network of other transcription factors and identify an in vivo Ntl binding site that resembles the consensus T-box binding site (TBS) previously identified by in vitro studies. We show that the notochord-expressed gene floating head ( flh) is a direct transcriptional target of Ntl and that a combination of TBSs in the flh upstream region are required for Ntl-directed expression. Using our genome-scale data we have assembled a preliminary gene regulatory network that begins to describe mesoderm formation and patterning in the early zebrafish embryo.brachyury ͉ chromatin immunopreciptitation ͉ microarray E mbryonic development proceeds through a series of progressively more restricted cell states in which sets of state-specific genes are expressed in a finely controlled temporal and spatial order. This coordination of gene expression is brought about by the integration of signaling inputs and binding of transcription factors at cis-regulatory modules (CRMs) associated with target genes, and can be described by a gene regulatory network (GRN). Such GRNs have been useful in understanding how development proceeds in the early lineages of sea urchins and ascidians (1, 2). However, although GRNs using data from single gene studies have been used to describe aspects of Xenopus mesendoderm and lamprey neural crest development (3, 4) a systematic approach to building a GRN by genome-scale analysis has not yet been used to describe early cell fate commitment in developing vertebrate embryos. Understanding how transcriptional regulation drives cell fate commitment in vertebrates is essential not only in understanding their development, but also for informing future efforts to recapitulate cell restriction to different tissue lineages for stem cell-based replacement therapies (5). We have thus set out to assemble a GRN that can describe vertebrate mesoderm development using zebrafish as a model system to identify targets of a key transcriptional regulator, No tail (Ntl).Ntl is a zebrafish ortholog of Brachyury, a T-domain transcription factor that is expressed as an early response to mesoderm induction and plays a central role in mesoderm development in all vertebrates. For instance, studies in mice, Xenopus, and zebrafish reveal that Brachyury orthologs influence many aspects of mesoderm specification and patterning, being required for formation of the notochord and posterior somites, for normal cell movements during gastrulation and tail outgrowth, and for establishment of left-right asymmetry (reviewed in refs. 6, 7).Here, we use chromatin immunoprecipitation combined with zebrafish genomic microarrays (ChIP-chip) to survey binding of Ntl at promoter regions. We show that Ntl binds the promoters of transcription factors implicated in posterior identity, muscle specification, cell movements, ...

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Section: Ntl Binds Mesodermally Expressed Genes Involved In Transcripmentioning

confidence: 86%

Section: Ntl Binds Mesodermally Expressed Genes Involved In Transcripmentioning

confidence: 99%

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

Morley

Lachani

Keefe

et al. 2009

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

109

118

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show abstract

“…This finding raises an important question, namely, what prevents no tail from inappropriately specifying axial mesoderm fate in these cells? A recent study has shown that expression of Tbx6, or even the Tbx6 DNA-binding domain alone, in regions of no tail expression produces similar phenotypes to those resulting from the expression of the No Tail antagonist NtlEnR-myc (Goering et al, 2003). Furthermore, the activity of a Tbx6-myc fusion mimicked that of the NtlEnR-myc construct, antagonizing No Tail activity when coexpressed in animal cap assays.…”

Section: A Conserved Genetic Pathway For Paraxial Mesoderm Vs Notochmentioning

confidence: 99%

“…However, this finding is due to a degree of redundancy early in development that is revealed by analysis of ntl Ϫ ;spt Ϫ double mutants. Although embryos heterozygous for no tail loss-of-function mutations show no phenotypic defects, when combined with loss of spadetail function, an enhancement of the spadetail mutant phenotype occurs (Amacher et al, 2002;Goering et al, 2003). As gastrulation proceeds, the cells of the hypoblast begin to refine their expression of both genes, with spadetail becoming restricted primarily to the paraxial mesoderm progenitors and no tail restricted to the notochord (Schulte-Merker et al, 1992;Griffin et al, 1998).…”

Section: T-box Genes Regulate Paraxial Mesoderm Developmentmentioning

confidence: 99%

T‐box genes in early embryogenesis

Showell

Binder

Conlon

2003

Developmental Dynamics

271

229

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“…Mutations in Tbx1 and TBX22 cause craniofacial defects that include cleft palate in mice and humans, respectively (34,35). A recent study in zebrafish (44) showed that closely related T-box transcription factors can interact either synergistically or antagonistically to regulate region specific developmental fate in overlapping expression domains. Further investigation of Tbx10 function in Dc mutants will lead to a better understanding of the molecular pathways involved in craniofacial development and CL͞P pathogenesis.…”

Section: Ectopic Expression Of Tbx10 In Transgenic Mice Recapitulatesmentioning

confidence: 99%

The cleft lip and palate defects inDancermutant mice result from gain of function of theTbx10gene

Bush

Lan

Jiang

2004

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

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An interacting network of T-box genes directs gene expression and fate in the zebrafish mesoderm

Cited by 76 publications

References 55 publications

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

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

T‐box genes in early embryogenesis

The cleft lip and palate defects inDancermutant mice result from gain of function of theTbx10gene

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