Project description:Recently, direct reprogramming between divergent lineages has been achieved by introducing cell-fate-determining transcription factors. This progress may provide alternative cell resources for drug discovery and regenerative medicine. However, the genetic manipulation may limit the future application of these approaches. In this study, we identified a novel small-molecule cocktail that directly converted fibroblasts into neuronal cell fate with a high yield up after 16-days of induction. After a further maturation stage, these chemically-induced neurons (CiNs) possessed neuron-specific expression patterns, generated action potentials and formed functional synapses. Gene expression profiling revealed the activation of neuronal specific genes in the early stage of small molecule treatment. Overall, our findings prove the principle of chemically-induced direct reprogramming of somatic cell fates across germ layers without genetic manipulation, and show that cell fate can be manipulated through disrupting initial cell program and activating target cell master genes with pure chemicals. Total of 15 samples were analyzed, including mouse fibroblasts, mouse cortical primary neurons and chemically-induced neurons by different duration of chemical induction (Day0, Day4, Day8, Day19) and different small-molecule cocktail (FICB, FICB-1)

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.

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:Cellular reprogramming using chemically defined conditions, without genetic manipulation, is a promising approach for generating clinically relevant cell types for regenerative medicine and drug discovery. However, small molecule-driven approaches for inducing lineage-specific stem cells from somatic cells across lineage boundaries have been challenging to develop. Here, we report highly efficient reprogramming of mouse fibroblasts into induced neural stem cell-like cells (ciNSLCs) using a cocktail of nine small molecules (M9). The resulting ciNSLCs closely resemble primary neural stem cells molecularly and functionally. Transcriptome analysis revealed that M9 induces a gradual and specific conversion of fibroblasts towards a neural fate. During reprogramming specific transcription factors such as Elk1 and Gli2 that are downstream of M9-induced signaling pathways bind and activate endogenous master neural genes to specify neural identity. Our study therefore provides an effective chemical approach for generating neural stem cells from mouse fibroblasts, and reveals mechanistic insights into underlying reprogramming process. Genome-wide epigenetic changes of H3K4me1, H3K4me3, H3K27me3, and H3K27ac were analyzed by CHIP-seq for tdMEFs from day 0 (ciNSLC), day 4 (D4), day 8 (D8) of M9-induced neural reprogramming, and ciNSLCs and pri-NPC.

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:In mammals, many organs lack robust regenerative abilities. Lost cells in impaired tissue could potentially be compensated by converting nearby cells in situ through in vivo reprogramming. Small molecule-induced reprogramming offers a spatiotemporally flexible and non-integrative strategy for altering cell fate, which is, in principle, favorable for in vivo reprogramming in organs with notoriously poor regenerative abilities, such as the brain. Here, we demonstrate that in adult mouse brain, small molecules can reprogram astrocytes into functional neurons. The in situ chemically induced neurons resemble endogenous neurons in gene expression profiles, electrophysiological properties and synaptic connectivity. Our study demonstrates, for the first time, in vivo chemical reprogramming in the adult brain and provides a novel approach for developing neuronal replacement therapies.

Project description:We recently demonstrated the chemical reprogramming of human somatic cells to pluripotent stem cells, which provides a fundamentally new approach for cell fate manipulation. However, the utility of this chemical approach is currently hampered by the slow kinetics. Here, by screening for new small-molecule boosters and systematically optimizing the original chemical reprogramming condition, we have established a robust, chemically defined protocol. With this new protocol, the entire chemical reprogramming process is remarkably accelerated, reducing the time needed from ~50 days to a minimum of 16 days. Moreover, this new protocol enables highly reproducible and efficient generation of human pluripotent stem cells from all 17 tested donors with a reprogramming efficiency of up to 31%. Our method provides a unique and powerful strategy for human cell fate manipulation and pluripotent stem cell manufacturing for cell-based therapeutic applications.

Project description:We recently demonstrated the chemical reprogramming of human somatic cells to pluripotent stem cells, which provides a fundamentally new approach for cell fate manipulation. However, the utility of this chemical approach is currently hampered by the slow kinetics. Here, by screening for new small-molecule boosters and systematically optimizing the original chemical reprogramming condition, we have established a robust, chemically defined protocol. With this new protocol, the entire chemical reprogramming process is remarkably accelerated, reducing the time needed from ~50 days to a minimum of 16 days. Moreover, this new protocol enables highly reproducible and efficient generation of human pluripotent stem cells from all 17 tested donors with a reprogramming efficiency of up to 31%. Our method provides a unique and powerful strategy for human cell fate manipulation and pluripotent stem cell manufacturing for cell-based therapeutic applications.

Project description:We recently demonstrated the chemical reprogramming of human somatic cells to pluripotent stem cells, which provides a fundamentally new approach for cell fate manipulation. However, the utility of this chemical approach is currently hampered by the slow kinetics. Here, by screening for new small-molecule boosters and systematically optimizing the original chemical reprogramming condition, we have established a robust, chemically defined protocol. With this new protocol, the entire chemical reprogramming process is remarkably accelerated, reducing the time needed from ~50 days to a minimum of 16 days. Moreover, this new protocol enables highly reproducible and efficient generation of human pluripotent stem cells from all 17 tested donors with a reprogramming efficiency of up to 31%. Our method provides a unique and powerful strategy for human cell fate manipulation and pluripotent stem cell manufacturing for cell-based therapeutic applications.