Zelda Binding in the Early Drosophila melanogaster Embryo Marks Regions Subsequently Activated at the Maternal-to-Zygotic Transition

Harrison, Melissa M.; Li, Xiaoyong; Kaplan, Tommy; Botchan, Michael R.; Eisen, Michael B.

doi:10.1371/journal.pgen.1002266

Cited by 326 publications

(616 citation statements)

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“…Vielfaltig is sufficient to activate enhancers that contain TAGteam motifs and required for early gene expression and cellularization (Liang et al 2008). While this work was under revision, it has further been shown that Vielfaltig binds to ;60% of all genomic instances of the TAGteam motif (Harrison et al 2011;Nien et al 2011). Our demonstration that Vielfaltig is a key determinant of early binding is intriguing and suggests that Vielfaltig might help to open (or keep open) chromatin and allow TFs to access their binding sites on DNA thereby defining early enhancers.…”

Section: Vielfaltig's Tagteam Motif Is a Key Regulator Of Early Tf Bimentioning

confidence: 92%

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

et al. 2012

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The regulation of gene expression is mediated at the transcriptional level by enhancer regions that are bound by sequence-specific transcription factors (TFs). Recent studies have shown that the in vivo binding sites of single TFs differ between developmental or cellular contexts. How this context-specific binding is encoded in the cis-regulatory DNA sequence has, however, remained unclear. We computationally dissect context-specific TF binding sites in Drosophila, Caenorhabditis elegans, mouse, and human and find distinct combinations of sequence motifs for partner factors, which are predictive and reveal specific motif requirements of individual binding sites. We predict that TF binding in the early Drosophila embryo depends on motifs for the early zygotic TFs Vielfaltig (also known as Zelda) and Tramtrack. We validate experimentally that the activity of Twist-bound enhancers and Twist binding itself depend on Vielfaltig motifs, suggesting that Vielfaltig is more generally important for early transcription. Our finding that the motif content can predict contextspecific binding and that the predictions work across different Drosophila species suggests that characteristic motif combinations are shared between sites, revealing context-specific motif codes (cis-regulatory signatures), which appear to be conserved during evolution. Taken together, this study establishes a novel approach to derive predictive cis-regulatory motif requirements for individual TF binding sites and enhancers. Importantly, the method is generally applicable across different cell types and organisms to elucidate cis-regulatory sequence determinants and the corresponding trans-acting factors from the increasing number of tissue-and cell-type-specific TF binding studies.

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Section: Vielfaltig's Tagteam Motif Is a Key Regulator Of Early Tf Bimentioning

confidence: 92%

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

et al. 2012

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“…The maternal transcription factor Zelda (Zld; zinc finger early Drosophila activator) plays a primary role for the onset of zygotic genome activation in Drosophila embryos (Liang et al 2008;Nien et al 2011). Zld protein is present in nuclei considerably earlier than other key maternal transcription factors such as Bicoid (Bcd) and Dorsal (Dl) proteins and is bound to gene regulatory regions prior to zygotic genome activation (Harrison et al 2011;Nien et al 2011). Zld binding increases DNA accessibility and facilitates the binding of other transcription factors, including Bcd and Dl, to target enhancers (Foo et al 2014;Xu et al 2014 (Foo et al 2014).…”

Section: Pioneer Factors In Zygotic Genome Activationmentioning

confidence: 99%

“…Inducing zygotic genome activation Liang et al 2008 Increasing DNA accessibility in native chromatin Harrison et al 2011;Foo et al 2014;Xu et al 2014 Class V Pou (e.g., Oct3/4, Pou5f3) Zygotic genome activation (zebrafish/mouse) Inducing zygotic genome activation Foygel et al 2008;Lee et al 2013 Binding to target sites before zygotic genome activation Leichsenring et al 2013 Reprogramming from fibroblast to iPSCs (mouse/human) Inducing reprogramming Takahashi and Yamanaka 2006 Binding to chromatin that is not DNase-sensitive and not premarked by common histone modifications in vivo Soufi et al 2012 Group B1 Sox (e.g., Sox2) Zygotic genome activation (zebrafish/mouse) Inducing zygotic genome activation Pan and Schultz 2011;Lee et al 2013 Reprogramming from fibroblast to iPSCs (mouse/human) Inducing reprogramming Takahashi and Yamanaka 2006 Binding to chromatin that is nonhypersensitive and not premarked by common histone modifications in vivo Soufi et al 2012 Cancer progression (mouse/human) Inducing tumor formation Bass et al 2009;Boumahdi et al 2014 Klf4…”

Section: Updike and Mango 2006mentioning

confidence: 99%

Pioneer transcription factors in cell reprogramming

2014

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A subset of eukaryotic transcription factors possesses the remarkable ability to reprogram one type of cell into another. The transcription factors that reprogram cell fate are invariably those that are crucial for the initial cell programming in embryonic development. To elicit cell programming or reprogramming, transcription factors must be able to engage genes that are developmentally silenced and inappropriate for expression in the original cell. Developmentally silenced genes are typically embedded in ''closed'' chromatin that is covered by nucleosomes and not hypersensitive to nuclease probes such as DNase I. Biochemical and genomic studies have shown that transcription factors with the highest reprogramming activity often have the special ability to engage their target sites on nucleosomal DNA, thus behaving as ''pioneer factors'' to initiate events in closed chromatin. Other reprogramming factors appear dependent on pioneer factors for engaging nucleosomes and closed chromatin. However, certain genomic domains in which nucleosomes are occluded by higher-order chromatin structures, such as in heterochromatin, are resistant to pioneer factor binding. Understanding the means by which pioneer factors can engage closed chromatin and how heterochromatin can prevent such binding promises to advance our ability to reprogram cell fates at will and is the topic of this review.Cell fate control represents the most extreme form of gene regulation. Genes specific to the function of a particular type of cell may be antagonistic to the function of another type of cell, so nature has evolved diverse regulatory mechanisms to ensure stable patterns of gene activation and repression. In prokaryotes, self-sustaining regulatory networks of transcription factors bound to DNA can be sufficient to regulate gene activation and repression (Ptashne 2011). In eukaryotes, ;200-base-pair (bp) segments of the genome are wound nearly twice around an octamer of the four core histones to form nucleosomes, providing steric constraints on how transcription factors can bind DNA (Kornberg and Lorch 1999). As described below, pioneer transcription factors have the special property of being able to overcome such constraints, enabling the factors to engage closed chromatin that is not accessible by other types of transcription factors (Fig. 1). However, further higher-order packaging of nucleosomes into heterochromatin can occlude access to DNA altogether, presenting an additional barrier to cell fate conversion (Fig. 1). This review focuses on the most recent studies of pioneer factors in cell programming and reprogramming, how pioneer factors have special chromatinbinding properties, and facilitators and impediments to chromatin binding. We project that such knowledge will greatly aid future efforts to change the fates of cells at will for research, diagnostic, and therapeutic purposes.

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“…Part of the answer involves transcription of Twine-degrading factors, 18 most likely regulated by Vielfältig/Zelda, the key transcriptional activator of the zygotic genome at the MBT. [20][21][22] In addition, precise control of timing is determined by the ability of the embryo to measure the ratio of nuclear content to the amount of cytoplasm (the nucleocytoplasmic ratio). At each cell cycle the amount of DNA doubles, and at a set number of cycles, which differs among organisms, the embryo senses through a still unclear mechanism that a correct ratio has been reached, and this initiates the degradation of Twine.…”

Section: The Midblastula Transition: Introducing Cell Cycle Complexitmentioning

confidence: 99%

“…5 Although a pre-MBT requirement for zygotic gene expression seems to be at odds with the concept that the zygotic genome is not transcribed before the MBT, recent evidence shows that Vielfältig/Zelda can surprisingly transcribe many genes prior to the MBT. 21,22,25 But why does Grapes/Chk1 cause pre-MBT degradation of String but not Twine? Mutation of the consensus Chk1 phosphorylation sites in Twine does not affect its stability, demonstrating that String and Twine are not regulated the same way.…”

Section: The Midblastula Transition: Introducing Cell Cycle Complexitmentioning

confidence: 99%

Cdc25 and the importance of G₂control

Bouldin¹,

Kimelman

2014

Cell Cycle

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Zelda Binding in the Early Drosophila melanogaster Embryo Marks Regions Subsequently Activated at the Maternal-to-Zygotic Transition

Cited by 326 publications

References 40 publications

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

Pioneer transcription factors in cell reprogramming

Cdc25 and the importance of G₂control

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Zelda Binding in the Early Drosophila melanogaster Embryo Marks Regions Subsequently Activated at the Maternal-to-Zygotic Transition

Cited by 326 publications

References 40 publications

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

Uncovering cis-regulatory sequence requirements for context-specific transcription factor binding

Pioneer transcription factors in cell reprogramming

Cdc25 and the importance of G2control

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Cdc25 and the importance of G₂control