Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Cell-fate conversion generally presumes the activity of reprogramming effectors to both introduce fate programs of the target cell type and erase the identity of starting cell population. Here, we reveal novel insights into the activity of microRNAs, miR-9/9* and miR-124 (miR-9/9*-124) as reprogramming agents that orchestrate direct conversion of human fibroblasts by first eradicating fibroblast identity and promoting uniform transition to a neuronal state in sequence. Among the direct target genes of miR-9/9*-124, we identify KLF-family transcription factors whose repression is critical for erasing fibroblast fate. The subsequent upregulation of a small nuclear RNA, RN7SK induces accessibilities of chromatin regions and neuronal gene activation, pushing the reprogramming cells to a neuronal state. Our study defines deterministic components in the reprogramming cascade by microRNAs.

Project description:Ectopic expression of neuronal microRNAs (miRNAs), miR-9/9* and miR-124 (miR-9/9*-124) in adult human fibroblasts has been found to evoke extensive reconfigurations of the chromatin and direct the fate conversion to neurons. We found that miR-9/9* and miR-124 led to the repression of REST, a transcriptional repressor of neuronal genes, during microRNA-mediated neuronal conversion and knockdown of REST enhanced the activation of BAF53b, a mature neuronal marker. Furthermore, time series analysis of the transcriptome of cells undergoing the miR-9/9*-124-induced conversion indicated upregulated genetic pathways that were predicted to be targeted by REST although the transcript level of REST remained unchanged (Abernathy et al., 2017). Therefore, we reasoned that knocking down REST in addition to miR-9/9*-124 at an early time point (day 7), in which REST repression is minimally evident during neuronal conversion, would speed up the adoption of neuronal identity. We performed the RNA-seq analysis to compared differentially expressed genes (DEGs) between human adult fibroblasts expressing control shRNA (shCTL) and reprogramming cells expressing shCTL or shREST at day 7. Finally, we found that the repression of REST constitutes an important component of microRNA-mediated neuronal reprogramming of human fibroblasts.