Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Phase Separation of FOXA1 Unpacks the Condensed Chromatin to Function as a Pioneer Factor

Project description:Phase Separation of FOXA1 Unpacks the Condensed Chromatin to Function as a Pioneer Factor [ATAC-seq]

Project description:Phase Separation of FOXA1 Unpacks the Condensed Chromatin to Function as a Pioneer Factor [ChIP-seq]

Project description:Phase Separation of FOXA1 Unpacks the Condensed Chromatin to Function as a Pioneer Factor [RNA-seq]

Project description:Phase Separation of FOXA1 Unpacks the Condensed Chromatin to Function as a Pioneer Factor (NIH-3T3 cells)

Project description:Pioneer transcription factors (TFs) exhibit a special ability to bind to and open closed chromatin, facilitating engagement by other regulatory factors involved in gene activation or repression. Chemical probes are lacking for pioneer TFs, which has hindered their mechanistic investigation in cells. Here, we report electrophilic small molecules that stereoselectively and site-specifically bind the pioneer TF, FOXA1, at a cysteine (C258) within the forkhead DNA-binding domain. We show that these covalent ligands react with FOXA1 in a DNA-dependent manner and rapidly remodel its pioneer activity in prostate cancer cells reflected in redistribution of FOXA1 binding across the genome and directionally correlated changes in chromatin accessibility. Motif analysis supports a mechanism where the covalent ligands relax the canonical DNA binding preference of FOXA1 by strengthening interactions with suboptimal ancillary sequences in predicted proximity to C258. Our findings reveal a striking plasticity underpinning the pioneering function of FOXA1 that can be controlled by small molecules.

Project description:Pioneer transcription factors (TFs) exhibit a special ability to bind to and open closed chromatin, facilitating engagement by other regulatory factors involved in gene activation or repression. Chemical probes are lacking for pioneer TFs, which has hindered their mechanistic investigation in cells. Here, we report electrophilic small molecules that stereoselectively and site-specifically bind the pioneer TF, FOXA1, at a cysteine (C258) within the forkhead DNA-binding domain. We show that these covalent ligands react with FOXA1 in a DNA-dependent manner and rapidly remodel its pioneer activity in prostate cancer cells reflected in redistribution of FOXA1 binding across the genome and directionally correlated changes in chromatin accessibility. Motif analysis supports a mechanism where the covalent ligands relax the canonical DNA binding preference of FOXA1 by strengthening interactions with suboptimal ancillary sequences in predicted proximity to C258. Our findings reveal a striking plasticity underpinning the pioneering function of FOXA1 that can be controlled by small molecules.