Project description:While chromatin presents a barrier to the binding of many transcription factors, pioneer factors access nucleosomal targets and promote chromatin opening. Despite binding to target motifs in closed chromatin, many pioneer factors display cell-type specific binding and activity. The mechanisms governing pioneer-factor occupancy and the relationship between chromatin occupancy and opening remain unclear. We studied three Drosophila transcription factors with distinct DNA-binding domains and biological functions: Zelda, Grainy head, and Twist. We demonstrated that the level of chromatin occupancy is a key determinant of activity. Multiple factors regulate occupancy, including motif content, local chromatin, and protein concentration. Regions outside the DNA-binding domain are required for binding and chromatin opening. Our results show that pioneering activity is not a binary feature intrinsic to a protein but occurs on a spectrum and is regulated by a variety of protein-intrinsic and cell-type-specific features.

Project description:While chromatin presents a barrier to the binding of many transcription factors, pioneer factors access nucleosomal targets and promote chromatin opening. Despite binding to target motifs in closed chromatin, many pioneer factors display cell-type specific binding and activity. The mechanisms governing pioneer-factor occupancy and the relationship between chromatin occupancy and opening remain unclear. We studied three Drosophila transcription factors with distinct DNA-binding domains and biological functions: Zelda, Grainy head, and Twist. We demonstrated that the level of chromatin occupancy is a key determinant of activity. Multiple factors regulate occupancy, including motif content, local chromatin, and protein concentration. Regions outside the DNA-binding domain are required for binding and chromatin opening. Our results show that pioneering activity is not a binary feature intrinsic to a protein but occurs on a spectrum and is regulated by a variety of protein-intrinsic and cell-type-specific features.

Project description:While chromatin presents a barrier to the binding of many transcription factors, pioneer factors access nucleosomal targets and promote chromatin opening. Despite binding to target motifs in closed chromatin, many pioneer factors display cell-type specific binding and activity. The mechanisms governing pioneer-factor occupancy and the relationship between chromatin occupancy and opening remain unclear. We studied three Drosophila transcription factors with distinct DNA-binding domains and biological functions: Zelda, Grainy head, and Twist. We demonstrated that the level of chromatin occupancy is a key determinant of activity. Multiple factors regulate occupancy, including motif content, local chromatin, and protein concentration. Regions outside the DNA-binding domain are required for binding and chromatin opening. Our results show that pioneering activity is not a binary feature intrinsic to a protein but occurs on a spectrum and is regulated by a variety of protein-intrinsic and cell-type-specific features.

Project description:Pioneer transcription factors initiate changes in gene expression by binding to cis-regulatory modules and promoting chromatin accessibility. It is suggested that this activity is an essential first step in priming these sites for the binding of other factors. Nonetheless, it is unclear whether pioneering activity is always required when these factors are present during development. The highly conserved, essential transcription factor Grainy head was recently identified as a pioneer factor in Drosophila larval imaginal discs, yet Grainy head is present throughout development. To determine whether Grainy head maintains its pioneering role throughout development, we performed ATAC-seq on embryos lacking either maternal or zygotic Grainy head at three stages of development (stage 5, stage 6, and stage 15). Surprisingly, we discovered that neither maternal nor zygotic Grainy head are required for chromatin accessibility in early embryogenesis. Nonetheless, we find that Grainy head binding is correlated with some cis-regulatory modules that gain chromatin accessibility at gastrulation. Intriguingly, later in embryogenesis Grainy head gains a role in promoting chromatin accessibility. Additionally, we determined that Grainy head is able to remain bound to mitotic chromatin, like other pioneer factors, yet this ability is separate from its pioneering activity. Our data reveal that Grainy head pioneering activity is temporally, suggesting that other unidentified pioneer factors compensate for the loss of Grainy head.

Project description:GATA4 is a pioneer transcription factor. The mechanisms by which pioneer factors select and occupy specific loci, open chromatin, and activate enhancers is not well understood. To address the influence of partner, non-pioneer factors on pioneer factor activity, we analyzed the effect of NKX2-5 or ETS1 on GATA4 pioneer activity. NIH3T3 cells were transduced with lentivirus to obtain stable cell lines that express GFP (control), GATA4 (G), NKX2-5 (N), ETS1 (E), GATA4+NKX2-5 (GN), and GATA4+ETS1 (GE). We measured chromatin accessibility using ATAC-seq, and enhancer activation using H3K27ac. From these measurements we determined GATA4, GATA4+ETS, and GATA4+NKX2-5 pioneer binding, pioneer opening, and pioneer enhancer activation. Our results show that ETS1 or NKX2-5 alter GATA4 pioneer binding, opening, and enhancer activation.

Project description:Pioneer factors are transcription factors (TFs) that have the unique ability to recognise their target DNA sequences within closed chromatin. Whereas their interactions with cognate DNA is similar to other TFs, their ability to interact with chromatin remains poorly understood. Having previously defined the modalities of DNA interactions for the pioneer factor Pax7, we have now used natural isoforms of this pioneer as well as deletion and replacement mutants to investigate the Pax7 structural requirements for chromatin interaction and opening. We show that the GL+ natural isoform of Pax7 that has two extra amino acids within the DNA binding paired domain is unable to activate the melanotrope transcriptome and to fully activate a large subset of melanotrope-specific enhancers targeted for Pax7 pioneer action. This enhancer subset remains in the primed state rather than being fully activated, despite the GL+ isoform having similar intrinsic transcriptional activity as the GL- isoform. C-terminal deletions of Pax7 lead to the same loss of pioneer ability, with similar reduced recruitments of the cooperating TF Tpit and of the co-regulators Ash2 and BRG1. This suggest complex interrelations between the DNA binding and C-terminal domains of Pax7 that are crucial for its chromatin opening pioneer ability.

Project description:Pioneer factors are transcription factors (TFs) that have the unique ability to recognise their target DNA sequences within closed chromatin. Whereas their interactions with cognate DNA is similar to other TFs, their ability to interact with chromatin remains poorly understood. Having previously defined the modalities of DNA interactions for the pioneer factor Pax7, we have now used natural isoforms of this pioneer as well as deletion and replacement mutants to investigate the Pax7 structural requirements for chromatin interaction and opening. We show that the GL+ natural isoform of Pax7 that has two extra amino acids within the DNA binding paired domain is unable to activate the melanotrope transcriptome and to fully activate a large subset of melanotrope-specific enhancers targeted for Pax7 pioneer action. This enhancer subset remains in the primed state rather than being fully activated, despite the GL+ isoform having similar intrinsic transcriptional activity as the GL- isoform. C-terminal deletions of Pax7 lead to the same loss of pioneer ability, with similar reduced recruitments of the cooperating TF Tpit and of the co-regulators Ash2 and BRG1. This suggest complex interrelations between the DNA binding and C-terminal domains of Pax7 that are crucial for its chromatin opening pioneer ability.

Project description:Pioneer factors are transcription factors (TFs) that have the unique ability to recognise their target DNA sequences within closed chromatin. Whereas their interactions with cognate DNA is similar to other TFs, their ability to interact with chromatin remains poorly understood. Having previously defined the modalities of DNA interactions for the pioneer factor Pax7, we have now used natural isoforms of this pioneer as well as deletion and replacement mutants to investigate the Pax7 structural requirements for chromatin interaction and opening. We show that the GL+ natural isoform of Pax7 that has two extra amino acids within the DNA binding paired domain is unable to activate the melanotrope transcriptome and to fully activate a large subset of melanotrope-specific enhancers targeted for Pax7 pioneer action. This enhancer subset remains in the primed state rather than being fully activated, despite the GL+ isoform having similar intrinsic transcriptional activity as the GL- isoform. C-terminal deletions of Pax7 lead to the same loss of pioneer ability, with similar reduced recruitments of the cooperating TF Tpit and of the co-regulators Ash2 and BRG1. This suggest complex interrelations between the DNA binding and C-terminal domains of Pax7 that are crucial for its chromatin opening pioneer ability.

Project description:Transcription factors induce dynamic chromatin reorganization during cell fate transition. Pioneer transcription factors are defined as their capability to engage chromatin by binding to nucleosomal DNA in closed chromatin and inducing chromatin opening. However, it has been also shown that these activities are context dependent. Only a subset of pioneer factors’ binding sites become open and the rest of binding sites remain closed. The molecular mechanisms of this context dependent action are still largely unknown. Here, we explore dynamic chromatin rearrangement during GATA3 dependent mesenchymal-to-epithelial transition (MET) in breast cancer cells. We found site-specific kinetic differences in chromatin binding, nucleosome remodeling and chromatin opening by the pioneer factor GATA3. We also identified that a chromatin remodeling enzyme, CHD4, negatively regulates the GATA3-mediated chromatin opening. The silencing of CHD4 induces abnormal chromatin opening leading to unnecessary gene expression for MET. Our study suggests the active regulation of chromatin potential by the chromatin remodeling enzyme for successful cellular reprogramming.

Project description:Transcription factors induce dynamic chromatin reorganization during cell fate transition. Pioneer transcription factors are defined as their capability to engage chromatin by binding to nucleosomal DNA in closed chromatin and inducing chromatin opening. However, it has been also shown that these activities are context dependent. Only a subset of pioneer factors’ binding sites become open and the rest of binding sites remain closed. The molecular mechanisms of this context dependent action are still largely unknown. Here, we explore dynamic chromatin rearrangement during GATA3 dependent mesenchymal-to-epithelial transition (MET) in breast cancer cells. We found site-specific kinetic differences in chromatin binding, nucleosome remodeling and chromatin opening by the pioneer factor GATA3. We also identified that a chromatin remodeling enzyme, CHD4, negatively regulates the GATA3-mediated chromatin opening. The silencing of CHD4 induces abnormal chromatin opening leading to unnecessary gene expression for MET. Our study suggests the active regulation of chromatin potential by the chromatin remodeling enzyme for successful cellular reprogramming.