Project description:Genome-wide transcriptional activity involves the binding of many transcription factors to thousands of sites in the genome. Determining which sites are directly driving transcription remains a challenge. Here we use acute protein depletion of the pioneer transcription factor SOX2 to establish its functionality in maintaining chromatin accessibility. We show that thousands of accessible sites are lost within an hour of protein depletion, indicating rapid turnover of these sites in the absence of pioneer factors. To understand the relationship with transcription we performed nascent transcription analysis and found that open chromatin sites that are maintained by SOX2 are highly predictive of gene expression, in contrast to all other SOX2 binding sites. We use CRISPR-Cas9 genome editing in the Klf2 locus to functionally validate a predicted regulatory element. We conclude that the regulatory activity of SOX2 is exerted largely at sites where it maintains accessibility and that other binding sites are largely dispensable for gene regulation.

Project description:Accessible chromatin enables the physical interaction of transcription factors with DNA. Mapping accessible chromatin regions with ATACseq can be used to identify the thousands of cis-regulatory elements in the mammalian genome. However, which of them contributes to gene expression remains an open question. In mouse embryonic stem cells (mESC), canonical transcription factor SOX2 is, among others, responsible for the establishment of chromatin accessibility. SOX2 acts as a pioneer factor that binds to inaccessible DNA and promotes the opening of the chromatin. However, not all regions bound by the pioneer factor undergo opening. To determine which accessible chromatin regions are directly controlled by SOX2, we depleted SOX2 from mESC using acute degradation by dTAG at high temporal resolution. The depletion leads to a rapid loss of chromatin accessibility (within 30 minutes) at SOX2 associated sites and a gradual gain of newly accessible sites. To understand the changes in transcription after SOX2 depletion we performed nascent transcript mapping using TTchemseq. This revealed that expression of hundreds of transcription units are also rapidly affected following SOX2 depletion.  The intersection of sites that lose accessibility and downregulated genes shows an enrichment within 40 kb around the TSS. Importantly, this is not the case for SOX2 binding sites as identified by ChIPseq. Therefore, accessible sites created by SOX2, rather than SOX2 occupancy, are relevant for gene expression. Furthermore, 60-70% of genes that lose expression can be explained by loss of accessibility. To validate this finding, we used CRISPR-Cas9 to delete an element that shows loss of accessibility in the vicinity of a downregulated gene. The deletion alone results in decreased expression of the gene, showing its importance in maintaining the transcription program. Our approach of acute depletion of a pioneer transcription factor combined with nascent transcript mapping allows us to predict functional regulatory elements. We show that constant maintenance of open chromatin regions relies directly on SOX2, and its disruption has drastic consequences on transcription.

Project description:Accessible chromatin enables the physical interaction of transcription factors with DNA. Mapping accessible chromatin regions with ATACseq can be used to identify the thousands of cis-regulatory elements in the mammalian genome. However, which of them contributes to gene expression remains an open question. In mouse embryonic stem cells (mESC), canonical transcription factor SOX2 is, among others, responsible for the establishment of chromatin accessibility. SOX2 acts as a pioneer factor that binds to inaccessible DNA and promotes the opening of the chromatin. However, not all regions bound by the pioneer factor undergo opening. To determine which accessible chromatin regions are directly controlled by SOX2, we depleted SOX2 from mESC using acute degradation by dTAG at high temporal resolution. The depletion leads to a rapid loss of chromatin accessibility (within 30 minutes) at SOX2 associated sites and a gradual gain of newly accessible sites. To understand the changes in transcription after SOX2 depletion we performed nascent transcript mapping using TTchemseq. This revealed that expression of hundreds of transcription units are also rapidly affected following SOX2 depletion.  The intersection of sites that lose accessibility and downregulated genes shows an enrichment within 40 kb around the TSS. Importantly, this is not the case for SOX2 binding sites as identified by ChIPseq. Therefore, accessible sites created by SOX2, rather than SOX2 occupancy, are relevant for gene expression. Furthermore, 60-70% of genes that lose expression can be explained by loss of accessibility. To validate this finding, we used CRISPR-Cas9 to delete an element that shows loss of accessibility in the vicinity of a downregulated gene. The deletion alone results in decreased expression of the gene, showing its importance in maintaining the transcription program. Our approach of acute depletion of a pioneer transcription factor combined with nascent transcript mapping allows us to predict functional regulatory elements. We show that constant maintenance of open chromatin regions relies directly on SOX2, and its disruption has drastic consequences on transcription.

Project description:The pioneer activity of transcription factors allows for opening of inaccessible regulatory elements and has been extensively studied in the context of cellular differentiation and reprogramming. In contrast, the function of pioneer activity in self-renewing cell divisions and across the cell cycle is poorly understood. Here we assessed the interplay between OCT4 and SOX2 in controlling chromatin accessibility of mouse embryonic stem cells. We found that OCT4 and SOX2 operate in a largely independent manner even at co-occupied sites, and that their cooperative binding is mostly mediated indirectly through regulation of chromatin accessibility. Controlled protein degradation strategies revealed that the uninterrupted presence of OCT4 is required for post-mitotic re-establishment and interphase maintenance of chromatin accessibility, and that highly OCT4-bound enhancers are particularly vulnerable to transient loss of OCT4 expression. Our study sheds light on the constant pioneer activity required to maintain the dynamic pluripotency regulatory landscape in an accessible state.

Project description:The pioneer activity of transcription factors allows for opening of inaccessible regulatory elements and has been extensively studied in the context of cellular differentiation and reprogramming. In contrast, the function of pioneer activity in self-renewing cell divisions and across the cell cycle is poorly understood. Here we assessed the interplay between OCT4 and SOX2 in controlling chromatin accessibility of mouse embryonic stem cells. We found that OCT4 and SOX2 operate in a largely independent manner even at co-occupied sites, and that their cooperative binding is mostly mediated indirectly through regulation of chromatin accessibility. Controlled protein degradation strategies revealed that the uninterrupted presence of OCT4 is required for post-mitotic re-establishment and interphase maintenance of chromatin accessibility, and that highly OCT4-bound enhancers are particularly vulnerable to transient loss of OCT4 expression. Our study sheds light on the constant pioneer activity required to maintain the dynamic pluripotency regulatory landscape in an accessible state.

Project description:The pioneer activity of transcription factors allows for opening of inaccessible regulatory elements and has been extensively studied in the context of cellular differentiation and reprogramming. In contrast, the function of pioneer activity in self-renewing cell divisions and across the cell cycle is poorly understood. Here we assessed the interplay between OCT4 and SOX2 in controlling chromatin accessibility of mouse embryonic stem cells. We found that OCT4 and SOX2 operate in a largely independent manner even at co-occupied sites, and that their cooperative binding is mostly mediated indirectly through regulation of chromatin accessibility. Controlled protein degradation strategies revealed that the uninterrupted presence of OCT4 is required for post-mitotic re-establishment and interphase maintenance of chromatin accessibility, and that highly OCT4-bound enhancers are particularly vulnerable to transient loss of OCT4 expression. Our study sheds light on the constant pioneer activity required to maintain the dynamic pluripotency regulatory landscape in an accessible state.

Project description:The pioneer activity of transcription factors allows for opening of inaccessible regulatory elements and has been extensively studied in the context of cellular differentiation and reprogramming. In contrast, the function of pioneer activity in self-renewing cell divisions and across the cell cycle is poorly understood. Here we assessed the interplay between OCT4 and SOX2 in controlling chromatin accessibility of mouse embryonic stem cells. We found that OCT4 and SOX2 operate in a largely independent manner even at co-occupied sites, and that their cooperative binding is mostly mediated indirectly through regulation of chromatin accessibility. Controlled protein degradation strategies revealed that the uninterrupted presence of OCT4 is required for post-mitotic re-establishment and interphase maintenance of chromatin accessibility, and that highly OCT4-bound enhancers are particularly vulnerable to transient loss of OCT4 expression. Our study sheds light on the constant pioneer activity required to maintain the dynamic pluripotency regulatory landscape in an accessible state.

Project description:The pioneer activity of transcription factors allows for opening of inaccessible regulatory elements and has been extensively studied in the context of cellular differentiation and reprogramming. In contrast, the function of pioneer activity in self-renewing cell divisions and across the cell cycle is poorly understood. Here we assessed the interplay between OCT4 and SOX2 in controlling chromatin accessibility of mouse embryonic stem cells. We found that OCT4 and SOX2 operate in a largely independent manner even at co-occupied sites, and that their cooperative binding is mostly mediated indirectly through regulation of chromatin accessibility. Controlled protein degradation strategies revealed that the uninterrupted presence of OCT4 is required for post-mitotic re-establishment and interphase maintenance of chromatin accessibility, and that highly OCT4-bound enhancers are particularly vulnerable to transient loss of OCT4 expression. Our study sheds light on the constant pioneer activity required to maintain the dynamic pluripotency regulatory landscape in an accessible state.

Project description:Pioneer transcription factors are able to recognise and bind their motif sequences in inaccessible or closed chromatin, and their ability to achieve this is required to establish new regulatory elements and transcriptional networks during development and cellular reprogramming. An essential feature of this pioneering activity is the transition from inaccessible chromatin to a nucleosome-depleted and accessible chromatin state typical of normal regulatory elements, and this is believed to facilitate further transcription factor binding events. However, the mechanisms by which many pioneer transcription factors achieve this remarkable feat remain elusive. Here we reveal that the pluripotency-associated pioneer factor OCT4 binds inaccessible chromatin to shape the chromatin accessibility, transcription factor co-binding and regulatory potential of thousands of distal regulatory elements in mouse embryonic stem cells, demonstrating that its pioneering activity is a feature of normal pluripotency, and not just reprogramming. The accessible chromatin formed at OCT4 binding sites relies on the chromatin remodelling factor BRG1, which is recruited to these sites by OCT4. The occupancy of BRG1 is then required to support OCT4/SOX2 co-binding and normal expression of the pluripotency-associated transcriptome, and this reliance on BRG1 reflects OCT4 binding dynamics during cellular reprograming and early mouse development. Together these observations reveal a distinct requirement for the chromatin remodelling factor BRG1 in shaping the pioneering activity of OCT4 and regulating the pluripotency network in embryonic stem cells.

Project description:Pioneer transcription factors are able to recognise and bind their motif sequences in inaccessible or closed chromatin, and their ability to achieve this is required to establish new regulatory elements and transcriptional networks during development and cellular reprogramming. An essential feature of this pioneering activity is the transition from inaccessible chromatin to a nucleosome-depleted and accessible chromatin state typical of normal regulatory elements, and this is believed to facilitate further transcription factor binding events. However, the mechanisms by which many pioneer transcription factors achieve this remarkable feat remain elusive. Here we reveal that the pluripotency-associated pioneer factor OCT4 binds inaccessible chromatin to shape the chromatin accessibility, transcription factor co-binding and regulatory potential of thousands of distal regulatory elements in mouse embryonic stem cells, demonstrating that its pioneering activity is a feature of normal pluripotency, and not just reprogramming. The accessible chromatin formed at OCT4 binding sites relies on the chromatin remodelling factor BRG1, which is recruited to these sites by OCT4. The occupancy of BRG1 is then required to support OCT4/SOX2 co-binding and normal expression of the pluripotency-associated transcriptome, and this reliance on BRG1 reflects OCT4 binding dynamics during cellular reprograming and early mouse development. Together these observations reveal a distinct requirement for the chromatin remodelling factor BRG1 in shaping the pioneering activity of OCT4 and regulating the pluripotency network in embryonic stem cells.