Transcriptional network underlying Caenorhabditis elegans vulval development

Inoué, Takao; Wang, Minqin; Ririe, Ted O.; Fernandes, Jolene S.; Sternberg, Paul W.

doi:10.1073/pnas.0408122102

Cited by 63 publications

(65 citation statements)

References 41 publications

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“…Among them are the promoters of terminal differentiation/selector genes of individual neurons (Hobert 2008), the transcriptional network underlying vulval development (Inoue et al 2005), and motifs in target genes of the TF PHA-4 that specifies pharyngeal identity (Gaudet and Mango 2002). In terms of length and distance from the TSS, the motifs we found resemble many known TFBS patterns in C. elegans and in other species.…”

Section: Genome Research 79mentioning

confidence: 51%

A novel candidate cis-regulatory motif pair in the promoters of germline and oogenesis genes in C. elegans

Linhart

Halperin²,

Darom³

et al. 2011

Genome Res.

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In this study we report on a novel pair of cis-regulatory motifs in promoter sequences of the nematode Caenorhabditis elegans. The motif pair exhibits extraordinary genomic traits: The order and the orientation of the two motifs are highly specific, and the distance between them is almost always one of two frequent distances. In contrast, the sequence between the motifs is variable across occurrences. Thus, the motif pair constitutes a nearly combinatorial sequence configuration. We further show that this module is conserved among, and unique to, the entire Caenorhabditis genus. By analyzing several gene expression data sets, our data suggest that this motif pair may function in germline development, oogenesis, and early embryogenesis. Finally, we verify that the motifs are indeed functional cis-regulatory elements using reporter constructs in transgenic C. elegans.

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Section: Genome Research 79mentioning

confidence: 51%

A novel candidate cis-regulatory motif pair in the promoters of germline and oogenesis genes in C. elegans

Linhart

Halperin²,

Darom³

et al. 2011

Genome Res.

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“…7) that likely target different subsets of these CRMs. Such feed-forward regulation is a prevalent feature in many developmental networks (Davidson et al 2002;Schroeder et al 2004;Inoue et al 2005;Koide et al 2005;Sandmann et al 2007a).…”

Section: Discussionmentioning

confidence: 99%

Temporal ChIP-on-chip reveals Biniou as a universal regulator of the visceral muscle transcriptional network

Jakobsen¹,

Braun²,

Astorga³

et al. 2007

Genes Dev.

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Smooth muscle plays a prominent role in many fundamental processes and diseases, yet our understanding of the transcriptional network regulating its development is very limited. The FoxF transcription factors are essential for visceral smooth muscle development in diverse species, although their direct regulatory role remains elusive. We present a transcriptional map of Biniou (a FoxF transcription factor) and Bagpipe (an Nkx factor) activity, as a first step to deciphering the developmental program regulating Drosophila visceral muscle development. A time course of chromatin immunoprecipitatation followed by microarray analysis (ChIP-on-chip) experiments and expression profiling of mutant embryos reveal a dynamic map of in vivo bound enhancers and direct target genes. While Biniou is broadly expressed, it regulates enhancers driving temporally and spatially restricted expression. In vivo reporter assays indicate that the timing of Biniou binding is a key trigger for the time span of enhancer activity. Although bagpipe and biniou mutants phenocopy each other, their regulatory potential is quite different. This network architecture was not apparent from genetic studies, and highlights Biniou as a universal regulator in all visceral muscle, regardless of its developmental origin or subsequent function. The regulatory connection of a number of Biniou target genes is conserved in mice, suggesting an ancient wiring of this developmental program.

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“…In C. elegans, direct transcription factor regulatory interaction networks have been identified through chromatin immunoprecipitation, 13,14 and yeast one-hybrid experiments, [15][16][17] while indirect regulatory interaction networks have mainly been identified through combinations of gene knockout or knockdown and gene reporter, RT-PCR or microarray experiments. [18][19][20][21] In the latter case, cis-regulatory motif finding algorithms have been applied in order to pinpoint the transcription factors directly responsible for the change in gene expression. 22 Reverse-engineering could significantly increase the knowledge on transcription regulatory networks in C. elegans and put forward a set of interactions worth the experimental time, cost and effort to validate them in vivo.…”

Section: Introductionmentioning

confidence: 99%

Computational and Systems Biology

Babu¹,

Mori²

2009

Mol. BioSyst.

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Over the last few decades, we have all witnessed an explosion in the amount and diversity of information that describes various living systems, including humans. This ranges from the availability of the complete genome sequence of over a thousand organisms to datasets describing expression levels of thousands of transcripts across different conditions to networks of interactions between different biological molecules. Thus it is clear that we are now in an exciting time in biology where the availability of such data permits us to investigate fundamental questions of a different magnitude and kind that are complementary to conventional approaches. This diversity in problems that one can currently address is well illustrated by the articles published in this themed issue of Molecular BioSystems entitled ''Computational and Systems Biology''. The excitement in this area and the scientific community is reflected in the fact that this special issue consists of over 50 papers with 19 reviews and 32 original research articles.

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Transcriptional network underlying Caenorhabditis elegans vulval development

Cited by 63 publications

References 41 publications

A novel candidate cis-regulatory motif pair in the promoters of germline and oogenesis genes in C. elegans

A novel candidate cis-regulatory motif pair in the promoters of germline and oogenesis genes in C. elegans

Temporal ChIP-on-chip reveals Biniou as a universal regulator of the visceral muscle transcriptional network

Computational and Systems Biology

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