Project description:Cellular reprogramming converts differentiated cells into induced pluripotent stem cells (iPSCs). However, this process is extremely inefficient, complicating mechanistic studies. Here, we identified and molecularly characterized rare, early intermediates poised to reprogram with up to 100% efficiency, without perturbing additional genes or pathways. Analysis of these cells uncovered transcription factors (e.g., Tfap2c, Bex2), which are critical for reprogramming but dispensable for pluripotency maintenance. Additionally, we observed striking patterns of chromatin hyperaccessibility at pluripotency loci, which preceded gene expression in poised intermediates. Finally, inspection of these hyperaccessible regions revealed a previously unappreciated early wave of DNA demethylation, which is uncoupled from de novo methylation of somatic regions late in reprogramming. Overall, our study underscores the importance of investigating the rare intermediates poised to produce iPSCs, provides novel insights into the mechanisms of reprogramming, and offers a valuable resource for the dissection of transcriptional and epigenetic dynamics intrinsic to cell fate change.

Project description:Cellular reprogramming converts differentiated cells into induced pluripotent stem cells (iPSCs). However, this process is extremely inefficient, complicating mechanistic studies. Here, we identified and molecularly characterized rare, early intermediates poised to reprogram with up to 100% efficiency, without perturbing additional genes or pathways. Analysis of these cells uncovered transcription factors (e.g., Tfap2c, Bex2), which are critical for reprogramming but dispensable for pluripotency maintenance. Additionally, we observed striking patterns of chromatin hyperaccessibility at pluripotency loci, which preceded gene expression in poised intermediates. Finally, inspection of these hyperaccessible regions revealed a previously unappreciated early wave of DNA demethylation, which is uncoupled from de novo methylation of somatic regions late in reprogramming. Overall, our study underscores the importance of investigating the rare intermediates poised to produce iPSCs, provides novel insights into the mechanisms of reprogramming, and offers a valuable resource for the dissection of transcriptional and epigenetic dynamics intrinsic to cell fate change.

Project description:Cellular reprogramming converts differentiated cells into induced pluripotent stem cells (iPSCs). However, this process is extremely inefficient, complicating mechanistic studies. Here, we identified and molecularly characterized rare, early intermediates poised to reprogram with up to 100% efficiency, without perturbing additional genes or pathways. Analysis of these cells uncovered transcription factors (e.g., Tfap2c, Bex2), which are critical for reprogramming but dispensable for pluripotency maintenance. Additionally, we observed striking patterns of chromatin hyperaccessibility at pluripotency loci, which preceded gene expression in poised intermediates. Finally, inspection of these hyperaccessible regions revealed a previously unappreciated early wave of DNA demethylation, which is uncoupled from de novo methylation of somatic regions late in reprogramming. Overall, our study underscores the importance of investigating the rare intermediates poised to produce iPSCs, provides novel insights into the mechanisms of reprogramming, and offers a valuable resource for the dissection of transcriptional and epigenetic dynamics intrinsic to cell fate change.

Project description:Factor-induced reprogramming of somatic cells into induced pluripotent stem cells (iPSCs) is inefficient, complicating mechanistic studies. Here, we examined defined intermediate cell populations poised to becoming iPSCs by genome-wide analyses. We show that induced pluripotency elicits two transcriptional waves, which are driven by c-Myc/Klf4 (first wave) and Oct4/Sox2/Klf4 (second wave). Cells that become refractory to reprogramming activate the first but fail to initiate the second transcriptional wave and can be rescued by elevated expression of all four factors. The establishment of bivalent domains occurs gradually after the first wave, whereas changes in DNA methylation take place after the second wave when cells acquire stable pluripotency. This integrative analysis allowed us to identify genes that act as roadblocks during reprogramming and surface markers that further enrich for cells prone to forming iPSCs. Collectively, our data offer new mechanistic insights into the nature and sequence of molecular events inherent to cellular reprogramming. DNA methylation profiles obtained at different timepoints during reprogramming of somatic cells: Day 0, +3, +6, +9 and iPSC

Project description:Novel Principles of Cellular Reprogramming Revealed by Prospective Isolation and Characterization of Rare Intermediates Poised to Generate iPSCs

Project description:Novel Principles of Cellular Reprogramming Revealed by Prospective Isolation and Characterization of Rare Intermediates Poised to Generate iPSCs [WGBS]

Project description:Novel Principles of Cellular Reprogramming Revealed by Prospective Isolation and Characterization of Rare Intermediates Poised to Generate iPSCs [ATAC-seq]

Project description:Factor-induced reprogramming of somatic cells into induced pluripotent stem cells (iPSCs) is inefficient, complicating mechanistic studies. Here, we examined defined intermediate cell populations poised to becoming iPSCs by genome-wide analyses. We show that induced pluripotency elicits two transcriptional waves, which are driven by c-Myc/Klf4 (first wave) and Oct4/Sox2/Klf4 (second wave). Cells that become refractory to reprogramming activate the first but fail to initiate the second transcriptional wave and can be rescued by elevated expression of all four factors. The establishment of bivalent domains occurs gradually after the first wave, whereas changes in DNA methylation take place after the second wave when cells acquire stable pluripotency. This integrative analysis allowed us to identify genes that act as roadblocks during reprogramming and surface markers that further enrich for cells prone to forming iPSCs. Collectively, our data offer new mechanistic insights into the nature and sequence of molecular events inherent to cellular reprogramming.

Project description:Novel Principles of Cellular Reprogramming Revealed by Prospective Isolation and Characterization of Rare Intermediates Poised to Generate iPSCs [RNA-seq 1]

Project description:Novel Principles of Cellular Reprogramming Revealed by Prospective Isolation and Characterization of Rare Intermediates Poised to Generate iPSCs [RNA-seq 2]