Project description:Human pluripotent stem cells (hPSCs) offer an unprecedented opportunity to model diverse cell types and tissues. To enable systematic exploration of the programming landscape mediated by transcription factors (TFs), we present the Human TFome, a comprehensive library containing 1,564 TF genes and 1,732 TF splice isoforms. By screening the library in three hPSC lines, we discovered 290 TFs, including 241 that were previously unreported, that induce differentiation in 4 days without alteration of external soluble or biomechanical cues. We used four of the hits to program hPSCs into neurons, fibroblasts, oligodendrocytes and vascular endothelial-like cells that have molecular and functional similarity to primary cells. Our cell-autonomous approach enabled parallel programming of hPSCs into multiple cell types simultaneously. We also demonstrated orthogonal programming by including oligodendrocyte-inducible hPSCs with unmodified hPSCs to generate cerebral organoids, which expedited in situ myelination. Large-scale combinatorial screening of the Human TFome will complement other strategies for cell engineering based on developmental biology and computational systems biology.

Project description:Now that many genomes have been sequenced and the products of newly identified genes have been annotated, the next goal is to engineer the desired phenotypes in organisms of interest. For the phenotypic engineering of microorganisms, we have developed novel artificial transcription factors (ATFs) capable of reprogramming innate gene expression circuits in Escherichia coli. These ATFs are composed of zinc finger (ZF) DNA-binding proteins, with distinct specificities, fused to an E. coli cyclic AMP receptor protein (CRP). By randomly assembling 40 different types of ZFs, we have constructed more than 6.4 x 10(4) ATFs that consist of 3 ZF DNA-binding domains and a CRP effector domain. Using these ATFs, we induced various phenotypic changes in E. coli and selected for industrially important traits, such as resistance to heat shock, osmotic pressure and cold shock. Genes associated with the heat-shock resistance phenotype were then characterized. These results and the general applicability of this platform clearly indicate that novel ATFs are powerful tools for the phenotypic engineering of microorganisms and can facilitate microbial functional genomic studies.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Primed epiblast stem cells (EpiSCs) can be reverted to a pluripotent embryonic stem cell (ESC)-like state by expression of single reprogramming factor. We used CRISPR activation to perform a genome-scale, reprogramming screen in EpiSCs and identified 142 candidate genes. Our screen validated a total of 50 genes, previously not known to contribute to reprogramming, of which we chose Sall1 for further investigation. We show that Sall1 augments reprogramming of mouse EpiSCs and embryonic fibroblasts and that these induced pluripotent stem cells are indeed fully pluripotent including formation of chimeric mice. We also demonstrate that Sall1 synergizes with Nanog in reprogramming and that overexpression in ESCs delays their conversion back to EpiSCs. Lastly, using RNA sequencing, we identify and validate Klf5 and Fam189a2 as new downstream targets of Sall1 and Nanog. In summary, our work demonstrates the power of using CRISPR technology in understanding molecular mechanisms that mediate complex cellular processes such as reprogramming.

Project description:Chromosomal architecture is known to influence gene expression, yet its role in controlling cell fate remains poorly understood. Reprogramming of somatic cells into pluripotent stem cells (PSCs) by the transcription factors (TFs) OCT4, SOX2, KLF4 and MYC offers an opportunity to address this question but is severely limited by the low proportion of responding cells. We have recently developed a highly efficient reprogramming protocol that synchronously converts somatic into pluripotent stem cells. Here, we used this system to integrate time-resolved changes in genome topology with gene expression, TF binding and chromatin-state dynamics. The results showed that TFs drive topological genome reorganization at multiple architectural levels, often before changes in gene expression. Removal of locus-specific topological barriers can explain why pluripotency genes are activated sequentially, instead of simultaneously, during reprogramming. Together, our results implicate genome topology as an instructive force for implementing transcriptional programs and cell fate in mammals.

Project description:Human pluripotent stem cell (hPSC)-derived cells offer an unprecedented opportunity to model diverse human tissue functions. However, the field lacks a generalized approach to rapidly and efficiently generate individual cell types of interest and to incorporate them into complex but defined tissues. To systematically explore the transcription factor (TF)-mediated hPSC programming landscape, we constructed the Human TFome: a comprehensive human TF library containing 1,564 TF (1,732 splice-isoforms). We discovered 241 previously unreported factors that individually converted hPSCs into diverse lineages with up to 99% efficiency in four days without alteration of external factors. Among these, we programmed neurons, fibroblasts, oligodendrocytes and endothelial cells that have molecular, transcriptomic and functional similarity to primary cells. Splice-isoform-specificity doubled endothelial conversion efficiency into in vivo-functional cells. Our cell-autonomous approach enabled parallel and orthogonal hPSCs programming into multiple cell types simultaneously without altering any microenvironmental cues. We generated in vivo-engraftable induced oligodendrocytes that expedited myelination within synthetically accelerated cerebral organoids.

Project description:Master transcription factors reprogram cell fate in multicellular eukaryotes. Pioneer transcription factors have prominent roles in this process because of their ability to contact their cognate binding motifs in closed chromatin. Reprogramming is pervasive in plants, whose development is plastic and tuned by the environment, yet little is known about pioneer transcription factors in this kingdom. Here, we show that the master transcription factor LEAFY (LFY), which promotes floral fate through upregulation of the floral commitment factor APETALA1 (AP1), is a pioneer transcription factor. In vitro, LFY binds to the endogenous AP1 target locus DNA assembled into a nucleosome. In vivo, LFY associates with nucleosome occupied binding sites at the majority of its target loci, including AP1. Upon binding, LFY 'unlocks' chromatin locally by displacing the H1 linker histone and by recruiting SWI/SNF chromatin remodelers, but broad changes in chromatin accessibility occur later. Our study provides a mechanistic framework for patterning of inflorescence architecture and uncovers striking similarities between LFY and animal pioneer transcription factor.

Project description:Reprogramming to induced pluripotency induces the switch of somatic cell identity to induced pluripotent stem cells (iPSCs). However, the mediators and mechanisms of reprogramming remain largely unclear. To elucidate the mediators and mechanisms of reprogramming, we used a siRNA-mediated knockdown approach for selected candidate genes during the conversion of somatic cells into iPSCs. We identified Tox4 as a novel factor that modulates cell fate through an assay that determined the efficiency of iPSC reprogramming. We found that Tox4 is needed early in reprogramming to efficiently generate early reprogramming intermediates, irrespective of the reprogramming conditions used. Tox4 enables proper exogenous reprogramming factor expression, and the closing and opening of putative somatic and pluripotency enhancers early during reprogramming, respectively. We show that the TOX4 protein assembles into a high molecular form. Moreover, Tox4 is also required for the efficient conversion of fibroblasts towards the neuronal fate, suggesting a broader role of Tox4 in modulating cell fate. Our study reveals Tox4 as a novel transcriptional modulator of cell fate that mediates reprogramming from the somatic state to the pluripotent and neuronal fate.This article has an associated First Person interview with the first author of the paper.

Project description:Human pluripotent stem cell (hPSC)-derived cells offer an unprecedented opportunity to model diverse human tissue functions. However, the field lacks a generalized approach to rapidly and efficiently generate individual cell types of interest and to incorporate them into complex but defined tissues. To systematically explore the transcription factor (TF)-mediated hPSC programming landscape, we constructed the Human TFome: a comprehensive human TF library containing 1,564 TF (1,732 splice-isoforms). We discovered 241 previously unreported factors that individually converted hPSCs into diverse lineages with up to 99% efficiency in four days without alteration of external factors. Among these, we programmed neurons, fibroblasts, oligodendrocytes and endothelial cells that have molecular, transcriptomic and functional similarity to primary cells. Splice-isoform-specificity doubled endothelial conversion efficiency into in vivo-functional cells. Our cell-autonomous approach enabled parallel and orthogonal hPSCs programming into multiple cell types simultaneously without altering any microenvironmental cues. We generated in vivo-engraftable induced oligodendrocytes that expedited myelination within synthetically accelerated cerebral organoids.

Project description:Human pluripotent stem cell (hPSC)-derived cells offer an unprecedented opportunity to model diverse human tissue functions. However, the field lacks a generalized approach to rapidly and efficiently generate individual cell types of interest and to incorporate them into complex but defined tissues. To systematically explore the transcription factor (TF)-mediated hPSC programming landscape, we constructed the Human TFome: a comprehensive human TF library containing 1,564 TF (1,732 splice-isoforms). We discovered 241 previously unreported factors that individually converted hPSCs into diverse lineages with up to 99% efficiency in four days without alteration of external factors. Among these, we programmed neurons, fibroblasts, oligodendrocytes and endothelial cells that have molecular, transcriptomic and functional similarity to primary cells. Splice-isoform-specificity doubled endothelial conversion efficiency into in vivo-functional cells. Our cell-autonomous approach enabled parallel and orthogonal hPSCs programming into multiple cell types simultaneously without altering any microenvironmental cues. We generated in vivo-engraftable induced oligodendrocytes that expedited myelination within synthetically accelerated cerebral organoids.