Project description:Mechanism controlling cell fate remains elusive. Chromatin remodeling complex interacts with transcription factors to colocalize across the genome and regulate region-specific epigenetic environment. Here, we propose an engineering approach for controlling cell fate through chromatin closing and opening. We utilize chromatin remodeling complex, BAF, known to activate gene expression by opening chromatin loci. By grafting BAF interacting motifs onto Nanog, we show that engineering factors could promote somatic cell reprogramming with Oct4. Furthermore, mutation on the interacting motifs render iPSC generation. The syntactic factors facilitate cell fate transition by recruiting BAF complex to modulate chromatin accessibility and reorganize cell state specific enhancers. Our findings reveal alternative methods to control cell fate by manipulating chromatin accessibility.

Project description:Mechanism controlling cell fate remains elusive. Chromatin remodeling complex interacts with transcription factors to colocalize across the genome and regulate region-specific epigenetic environment. Here, we propose an engineering approach for controlling cell fate through chromatin closing and opening. We utilize chromatin remodeling complex, BAF, known to activate gene expression by opening chromatin loci. By grafting BAF interacting motifs onto Nanog, we show that engineering factors could promote somatic cell reprogramming with Oct4. Furthermore, mutation on the interacting motifs render iPSC generation. The syntactic factors facilitate cell fate transition by recruiting BAF complex to modulate chromatin accessibility and reorganize cell state specific enhancers. Our findings reveal alternative methods to control cell fate by manipulating chromatin accessibility.

Project description:Mechanism controlling cell fate remains elusive. Chromatin remodeling complex interacts with transcription factors to colocalize across the genome and regulate region-specific epigenetic environment. Here, we propose an engineering approach for controlling cell fate through chromatin closing and opening. We utilize chromatin remodeling complex, BAF, known to activate gene expression by opening chromatin loci. By grafting BAF interacting motifs onto Nanog, we show that engineering factors could promote somatic cell reprogramming with Oct4. Furthermore, mutation on the interacting motifs render iPSC generation. The syntactic factors facilitate cell fate transition by recruiting BAF complex to modulate chromatin accessibility and reorganize cell state specific enhancers. Our findings reveal alternative methods to control cell fate by manipulating chromatin accessibility.

Project description:Mechanism controlling cell fate remains elusive. Chromatin remodeling complex interacts with transcription factors to colocalize across the genome and regulate region-specific epigenetic environment. Here, we propose an engineering approach for controlling cell fate through chromatin closing and opening. We utilize chromatin remodeling complex, BAF, known to activate gene expression by opening chromatin loci. By grafting BAF interacting motifs onto Nanog, we show that engineering factors could promote somatic cell reprogramming with Oct4. Furthermore, mutation on the interacting motifs render iPSC generation. The syntactic factors facilitate cell fate transition by recruiting BAF complex to modulate chromatin accessibility and reorganize cell state specific enhancers. Our findings reveal alternative methods to control cell fate by manipulating chromatin accessibility.

Project description:Chemical induction of pluripotency (CIP) is an ideal way to reprogram cell fate, but remains poorly understood. Here we report the development of an efficient CIP protocol and the chromatin accessibility dynamics (CAD) during CIP by ATAC-seq. CIP first reorganizes the somatic genome to an intermediate state that must be resolved by primarily closing loci opened earlier before reaching a pluripotent state with gradual opening of loci enriched with motifs for the OCT/SOX/KLF families. Bromodeoxyuridine, a critical ingredient of CIP, is responsible for both closing and opening critical loci, at least in part by preventing the opening of loci enriched with motifs for the AP1 family and facilitating the opening of loci enriched with SOX/KLF/GATA motifs. Our studies provide the first link between small molecules and nuclear architecture in the context of cell fate decisions.

Project description:Chemical induction of pluripotency (CIP) is an ideal way to reprogram cell fate, but remains poorly understood. Here we report the development of an efficient CIP protocol and the chromatin accessibility dynamics (CAD) during CIP by ATAC-seq. CIP first reorganizes the somatic genome to an intermediate state that must be resolved by primarily closing loci opened earlier before reaching a pluripotent state with gradual opening of loci enriched with motifs for the OCT/SOX/KLF families. Bromodeoxyuridine, a critical ingredient of CIP, is responsible for both closing and opening critical loci, at least in part by preventing the opening of loci enriched with motifs for the AP1 family and facilitating the opening of loci enriched with SOX/KLF/GATA motifs. Our studies provide the first link between small molecules and nuclear architecture in the context of cell fate decisions.

Project description:Chemical induction of pluripotency (CIP) is an ideal way to reprogram cell fate, but remains poorly understood. Here we report the development of an efficient CIP protocol and the chromatin accessibility dynamics (CAD) during CIP by ATAC-seq. CIP first reorganizes the somatic genome to an intermediate state that must be resolved by primarily closing loci opened earlier before reaching a pluripotent state with gradual opening of loci enriched with motifs for the OCT/SOX/KLF families. Bromodeoxyuridine, a critical ingredient of CIP, is responsible for both closing and opening critical loci, at least in part by preventing the opening of loci enriched with motifs for the AP1 family and facilitating the opening of loci enriched with SOX/KLF/GATA motifs. Our studies provide the first link between small molecules and nuclear architecture in the context of cell fate decisions.

Project description:The mammalian BRG1-associated factors (BAF) complex is a multi-subunit chromatin remodeling complex that is an important component of the embryonic stem cell (ESC) transcriptional regulatory network. However, the role of individual subunits in BAF complex targeting and function needs to be elucidated. Here, we find that the Bromodomain containing protein 9 (BRD9) defines a smaller, non-canonical BAF complex in mouse ESCs that is distinct from the canonical embryonic stem cell BAF (esBAF) and the polybromo-associated BAF (PBAF) complexes. This BRD9-containing BAF complex, or BBAF complex, uniquely incorporates the BRD4-interacting chromatin remodeling associated protein-like (BICRAL) or its paralog BICRA and lacks several esBAF subunits including BAF47, ARID1A and BAF57. We demonstrate that BBAF and esBAF complexes are targeted to different features of the genome and are co-bound with different sets of pluripotency transcription factors. Specifically, BBAF complexes co-localize with key regulators of naïve pluripotency, KLF4 and Sp5, on the genome. Consistent with this, we provide evidence that BBAF’s specific function is to regulate the transcription of genes involved in the maintenance of naïve pluripotency, including Nanog and Prdm14. Additionally, we show that BRD9 is displaced from chromatin by the selective BRD9 bromodomain inhibitor, I-BRD9, and that this leads to changes in target gene expression. Together, our results provide evidence for the identification of a new BAF complex, and demonstrate functionally specific roles for BAF complex assemblies in maintaining the transcriptional network of pluripotency.

Project description:Cell fate decisions are achieved with gene expression changes driven by lineage-specific transcription factors (TFs). These TFs depend on chromatin remodelers including the BAF complex to activate target genes. BAF complex subunits are essential for development and frequently mutated in cancer. Thus, interrogating how BAF complexes contribute to cell fate decisions is critical for human health. We examined the requirement for the catalytic BAF subunit BRG1 in neural progenitor cell (NPC) specification from human embryonic stem cells. During the earliest stages of differentiation, BRG1 was required to establish chromatin accessibility at neuroectoderm-specific enhancers. BRG1 depletion resulted in abnormal NPC populations that differentially expressed neuroectodermal TFs, were more prone to neuronal differentiation, and precociously formed neural crest lineages. These findings demonstrate that BRG1 mediates NPC specification by ensuring proper expression of lineage-specific TFs and appropriate activation of their transcriptional programs.

Project description:The exit from pluripotency or pluripotent-somatic transition (PST) landmarks an event of mammalian development, and is also a representative cell-fate transition model, but remains largely unresolved. Recently, we reported construction of robust JUN-induced PST completed in one cell cycle and whose dominant regulator SS18/BAFs (Brg1/Brahma-associated factors). However, the transition process in the chromatin architecture and the roles played by BAF are still unknown. Here we report the dynamic changes of chromatin accessibility during JUN-induced PST. Meanwhile, SS18/BAFs mediates PST process by relocating from pluripotent loci to AP-1 associated ones and once compromised, JUN fails to open chromatin and PST will be delayed. Furthermore, we show that the relocation of SS18/BAF partially relays on histone modification H3K27ac, instead of JUN-centric protein-protein interaction. These results reveal the orchestration of master transcription factor, epigenetic machine, and histone modification in the cell fate transition.