Project description:Pluripotent stem cells can be generated by pure small molecule compounds. However, only fibroblasts, a heterogeneous cell population, were reported for use in chemical reprogramming, and the efficiency is relatively low, raising the possibility that chemically induced pluripotent stem cells (CiPSCs) are derived from a specific cell subpopulation residing in fibroblast culture. Thus, it is of interest to know whether chemical reprogramming can be induced in other cell types, even using the same chemical cocktail. Here, using lineage tracing, we verify the generation of CiPSCs from fibroblasts. We further demonstrate that neural stem cells (NSCs) and small intestinal epithelial cells (IECs), cell types from the ectoderm and endoderm, respectively, can be chemically reprogrammed into pluripotent stem cells. CiPSCs derived from NSCs and IECs resemble mouse embryonic stem cells (ESCs) in terms of proliferation rate, global gene expression profiling, epigenetic status, self-renewal and differentiation capacity, and germline transmission competency. Interestingly, in the chemical reprogramming process from different cell types, a pluripotency gene Sall4 was commonly expressed in the initial stage, and the same core small molecules were required, suggesting conservatism underlying chemical reprogramming from different cell types. Moreover, the use of these small molecules should be fine-tuned to meet the requirement of reprogramming from different cell types. Together, these findings demonstrate that our reported chemical reprogramming approach can be reproduced in different cell types and suggest that chemical reprogramming is a promising strategy with the potential to be extended to more initial cell types.

Project description:Pluripotent stem cells can be generated from somatic cells by using pure chemicals.However, the cell fate dynamics and molecular events that occur during the chemical reprogramming process remain unclear. In this study, we found that the chemical reprogramming process requires the early formation of extra-embryonic endoderm (XEN)-like cells and a late transition from XEN-like cells to CiPSCs, a new route that differs from the pathway of transcription factor-induced reprogramming. Moreover, by more precisely manipulating the cell fate transition in a step-wise manner through the XEN-like state, we identified small-molecule boosters and established a robust chemical reprogramming system, with a yield up to 1,000-fold greater than that of the previously reported protocol. These findings demonstrate that chemical reprogramming is a unique and promising approach in the future manipulation of cell fates. We analyzed the gene expression profiles of intermediate cells obtained from diferent timepoints during chemical reprogramming process,using RNA-Sequencing. Embryo-derived XEN cells (eXENs), chemically-derived eXEN cell lines (CeXENs), embryonic stem cells (ESCs) and chemically-induced pluripotent stem cells (CiPSCs) are used as controls.

Project description:Chemical induced pluripotent stem cells (CiPSCs) have been successfully achieved and may provide an alternative and attractive source for stem cell-based therapy. Sufficient telomere lengths are critical for unlimited self-renewal and genomic stability of pluripotent stem cells. Dynamics of telomere reprogramming and whether and how telomeres are sufficiently elongated in the CiPSCs have remained to be understood. We show that CiPSCs acquire telomere lengthening with increasing passages after clonal formation. Both telomerase activity and recombination-based mechanisms are involved in the telomere elongation. Telomere lengths strongly indicate the degree of reprogramming, pluripotency and differentiation capacity of CiPSCs. Nevertheless, telomere damage and shortening occur at late stage of lengthy induction, limiting CiPSC formation. Recombination mechanism is not activated during induction until CiPSC clonal formation and passages. We find that histone crotonylation induced by crotonic acid can activate two-cell genes including Zscan4, alleviate telomere damage and shortening during induction and promote CiPSC generation. Moreover, crotonylation decreases abundance of heterochromatic H3K9me3 and HP1a at subtelomeres and Zscan4 loci. Taken together, telomere rejuvenation links to reprogramming and pluripotency of CiPSCs. Crotonylation facilitates telomere maintenance and enhances chemical induced reprogramming to pluripotency.

Project description:Pluripotent stem cells can be induced from somatic cells, providing an unlimited cell resource for regenerative medicine. However, genetic manipulation and difficult-to-manufacture strategies used in reprogramming limit their clinical applications. Here, we show pluripotency can be induced from mouse somatic cells by specific small-molecule compounds. The completely chemically-induced pluripotent stem cells (CiPSCs) can be stably maintained in embryonic stem cell (ESC) culture medium and resemble ESCs in terms of their gene expression profiles, epigenetic status, and potential for differentiation and germline transmission. These findings suggest that exogenous master genes are dispensable for cell fate reprogramming and pave the way for the clinical application of somatic reprogramming techniques. Pluripotent stem cells can be induced from somatic cells, providing an unlimited cell resource for regenerative medicine. However, genetic manipulation and difficult-to-manufacture strategies used in reprogramming limit their clinical applications. Here, we show pluripotency can be induced from mouse somatic cells by specific small-molecule compounds. The completely chemically-induced pluripotent stem cells (CiPSCs) can be stably maintained in embryonic stem cell (ESC) culture medium and resemble ESCs in terms of their gene expression profiles, epigenetic status, and potential for differentiation and germline transmission. These findings suggest that exogenous master genes are dispensable for cell fate reprogramming and pave the way for the clinical application of somatic reprogramming techniques. Chemicals' acronyms: V, VPA; C, CHIR; 6, 616452; T, tranylcypromine; F, FSK; Z, DZNep; P, PGE2; R, RG108; S, SRT1720; M, 2-Me-5HT; D, D4476; B, Sodium butyrate. To compare the global gene expression pofile of mouse embryonic fibroblasts (MEFs), mouse adult lung fibroblasts (MAFs), mouse neonatal fibroblasts (MNFs), adipose-derived stem cells (ADSCs), chemical induced pluripotent stem cells (CiPS), embryonic stem cells (ESCs) and OSKM-iPSCs. We profiled the mRNA expression of each sample by microarray (Mouse OneArray® v2, Phalanx). Different sample set was normalized for different purpose. Set1: MEFs1, CiPS34, MNF CIPS7, CiPS50 CiPS21, OSKM-iPS1 and ESCs1 were analyzed, each sample have three replicates; Set2: MNFs, MAFs, ADSCs, MNF CiPS1, MAF CiPS3, CiPS45, ADSC CiPS2, OSKM iPS2 and ESCs2 were analyzed, each sample have three replicates; Set3: WT MEFs, ESCs3, CiPS WT1 and CiPS WT2 were analyzed, each sample have two replicates; Set4: MEFs2, SKM-FSK1, SKM-FSK2 and ESCs4 were analyzed, each sample have three replicates; Set5: MEFs3, ESCs5, CiPSCs, D12, D20 and D32 were analyzed, each sample have two replicates.

Project description:Pluripotent stem cells can be induced from somatic cells, providing an unlimited cell resource for regenerative medicine. However, genetic manipulation and difficult-to-manufacture strategies used in reprogramming limit their clinical applications. Here, we show pluripotency can be induced from mouse somatic cells by specific small-molecule compounds. The completely chemically-induced pluripotent stem cells (CiPSCs) can be stably maintained in embryonic stem cell (ESC) culture medium and resemble ESCs in terms of their gene expression profiles, epigenetic status, and potential for differentiation and germline transmission. These findings suggest that exogenous master genes are dispensable for cell fate reprogramming and pave the way for the clinical application of somatic reprogramming techniques. Chemicals' acronym: V, VPA; C, CHIR; 6, 616452; T, tranylcypromine; F, FSK; Z, DZNep; P, PGE2; R, RG108; S, SRT1720; M, 2-Me-5HT; D, D4476; B, Sodium butyrate. mRNA expression analysis of mouse embryonic fibroblasts (MEFs), GFP- cells, GFP+ clusters,GFP+ colonies, embryonic stem cells (ESCs) and CiPSCs by RNA sequencing.

Project description:Pluripotent stem cells can be generated from somatic cells by using pure chemicals.However, the cell fate dynamics and molecular events that occur during the chemical reprogramming process remain unclear. In this study, we found that the chemical reprogramming process requires the early formation of extra-embryonic endoderm (XEN)-like cells and a late transition from XEN-like cells to CiPSCs, a new route that differs from the pathway of transcription factor-induced reprogramming. Moreover, by more precisely manipulating the cell fate transition in a step-wise manner through the XEN-like state, we identified small-molecule boosters and established a robust chemical reprogramming system, with a yield up to 1,000-fold greater than that of the previously reported protocol. These findings demonstrate that chemical reprogramming is a unique and promising approach in the future manipulation of cell fates.

Project description:Induced pluripotent stem cells (iPSCs) can be derived from somatic cells through ectopic expression of transcriptional factors or chemical cocktails. Chemical reprogramming might be safe than transcriptional factors since there is no integration of exogenous genes. However, there is still little direct evidence to prove this hypothesis. In this study, we have performed whole genome profiling of the DNA methylomes of mouse chemical iPSCs (CiPSCs), transcriptional factors induced iPSCs (TF-iPSCs) and embryonic stem cells (ESCs). We find that the methylation levels of high-CpG-density promoters (HCPs) and intermediate- CpG-density promoters (ICPs) have no significant difference among them, but low-CpG-density promoters (LCP) and three retrotransposons (LINEs, LTRs and SINEs) show preference to different methylation levels. Surprisingly, CiPSCs are hypomethylated than TF-iPSCs and the major difference of methylation levels lies in the intergenic regions while two iPSCs lines are generally hypermethylated compared to ESCs. Moveover, we find the methylation states of imprinting control regions (ICRs) and the expression of imprinted genes of CiPSCs are more resemble ESCs than TF-iPSCs. Our data first provide the epigenetic states of chemical induced pluripotent stem cells and compare the difference of mouse CiPSCs, TF-iPSCs and ESCs. These observations might affect ongoing choices of reprogramming methods for disease modeling and give some guides for potential therapeutic applications.

Project description:Induced pluripotent stem cells (iPSCs) can be derived from somatic cells through ectopic expression of transcriptional factors or chemical cocktails. Chemical reprogramming might be safe than transcriptional factors since there is no integration of exogenous genes. However, there is still little direct evidence to prove this hypothesis. In this study, we have performed whole genome profiling of the DNA methylomes of mouse chemical iPSCs (CiPSCs), transcriptional factors induced iPSCs (TF-iPSCs) and embryonic stem cells (ESCs). We find that the methylation levels of high-CpG-density promoters (HCPs) and intermediate- CpG-density promoters (ICPs) have no significant difference among them, but low-CpG-density promoters (LCP) and three retrotransposons (LINEs, LTRs and SINEs) show preference to different methylation levels. Surprisingly, CiPSCs are hypomethylated than TF-iPSCs and the major difference of methylation levels lies in the intergenic regions while two iPSCs lines are generally hypermethylated compared to ESCs. Moveover, we find the methylation states of imprinting control regions (ICRs) and the expression of imprinted genes of CiPSCs are more resemble ESCs than TF-iPSCs. Our data first provide the epigenetic states of chemical induced pluripotent stem cells and compare the difference of mouse CiPSCs, TF-iPSCs and ESCs. These observations might affect ongoing choices of reprogramming methods for disease modeling and give some guides for potential therapeutic applications.

Project description:Fibroblasts can be chemically induced to pluripotent stem cells (CiPSCs) through an extraembryonic endoderm (XEN)-like state or directly converted into other differentiated cell lineages. However, the mechanisms underlying chemically-induced cell fate reprogramming remain unclear. Here, a transcriptome-based screen of biologically active compounds uncovered that CDK8 inhibition was essential to enable chemically-induced reprogramming from fibroblasts into XEN-like cells, then CiPSCs. RNA-seq analysis showed that a CDK8 inhibitor, MSC2530818, inhibited pro-inflammatory pathways that suppress chemical reprogramming, and facilitated the induction of a multi-lineage priming state, indicating the establishment of plasticity in fibroblasts. CDK8 inhibition also resulted in chromatin accessibility profile and Pol II occupation profile similar to that under initial chemical reprogramming. Moreover, CDK8 inhibition greatly promoted transgene-mediated reprogramming of mouse fibroblasts into hepatocyte-like cells, and chemical reprogramming of human fibroblasts into adipocytes. These collective findings thus define CDK8 as a general molecular barrier in multiple cell reprogramming processes, and as a common target for inducing plasticity and cell fate conversion.

Project description:Fibroblasts can be chemically induced to pluripotent stem cells (CiPSCs) through an extraembryonic endoderm (XEN)-like state or directly converted into other differentiated cell lineages. However, the mechanisms underlying chemically-induced cell fate reprogramming remain unclear. Here, a transcriptome-based screen of biologically active compounds uncovered that CDK8 inhibition was essential to enable chemically-induced reprogramming from fibroblasts into XEN-like cells, then CiPSCs. RNA-seq analysis showed that a CDK8 inhibitor, MSC2530818, inhibited pro-inflammatory pathways that suppress chemical reprogramming, and facilitated the induction of a multi-lineage priming state, indicating the establishment of plasticity in fibroblasts. CDK8 inhibition also resulted in chromatin accessibility profile and Pol II occupation profile similar to that under initial chemical reprogramming. Moreover, CDK8 inhibition greatly promoted transgene-mediated reprogramming of mouse fibroblasts into hepatocyte-like cells, and chemical reprogramming of human fibroblasts into adipocytes. These collective findings thus define CDK8 as a general molecular barrier in multiple cell reprogramming processes, and as a common target for inducing plasticity and cell fate conversion.