Generation of induced pluripotent stem cells (iPSCs) by somatic cell reprogramming involves global epigenetic remodeling1. While several proteins are known to regulate chromatin marks associated with the distinct epigenetic states of cells before and after reprogramming2,3, the role of specific chromatin modifying enzymes in reprogramming remains to be determined. To address how chromatin-modifying proteins influence reprogramming, we used shRNAs to target genes in DNA and histone methylation pathways, and have identified positive and negative modulators of iPSC generation. While inhibition of the core components of the polycomb repressive complex 1 and 2, including the histone 3 lysine 27 methyltransferase Ezh2, reduced reprogramming efficiency, suppression of SUV39H1, YY1, and Dot1L enhanced reprogramming. Specifically, inhibition of the H3K79 histone methyltransferase Dot1L by shRNA or a small molecule accelerated reprogramming, significantly increased the yield of iPSC colonies, and substituted for Klf4 and c-Myc. Inhibition of Dot1L early in the reprogramming process is associated with a marked increase in two alternative factors, Nanog and Lin28, which play essential functional roles in the enhancement of reprogramming. Genome-wide analysis of H3K79me2 distribution revealed that fibroblast-specific genes associated with the epithelial to mesenchymal transition lose H3K79me2 in the initial phases of reprogramming. Dot1L inhibition facilitates the loss of this mark from genes that are fated to be repressed in the pluripotent state. These findings implicate specific chromatin-modifying enzymes as barriers to or facilitators of reprogramming, and demonstrate how modulation of chromatin-modifying enzymes can be exploited to more efficiently generate iPSCs with fewer exogenous transcription factors.
Leptin Receptor + (LepR + ) stromal cells in adult bone marrow are a critical source of growth factors, including Stem Cell Factor (SCF), for the maintenance of hematopoietic stem cells (HSCs) and early restricted progenitors 1 – 6 . LepR + cells are heterogeneous, including skeletal stem cells, osteogenic, and adipogenic progenitors 7 – 12 , though few markers have been available to distinguish these subsets or to compare their functions. Here we show expression of an osteogenic growth factor, Osteolectin 13 , 14 , distinguishes peri-arteriolar LepR + cells poised to undergo osteogenesis from peri-sinusoidal LepR + cells poised to undergo adipogenesis (but retaining osteogenic potential). Peri-arteriolar LepR + Osteolectin + cells are rapidly dividing, short-lived, osteogenic progenitors that increase in number after fracture and are depleted during aging. Deletion of Scf from adult Osteolectin + cells did not affect the maintenance of HSCs or most restricted progenitors but depleted common lymphoid progenitors (CLPs), impairing lymphopoiesis, bacterial clearance, and survival after acute bacterial infection. Peri-arteriolar Osteolectin + cell maintenance required mechanical stimulation. Voluntary running increased, while hindlimb unloading decreased, the frequencies of peri-arteriolar Osteolectin + cells and CLPs. Deletion of the mechanosensitive ion channel, Piezo1 , from Osteolectin + cells depleted Osteolectin + cells and CLPs. A peri-arteriolar niche for osteogenesis and lymphopoiesis in bone marrow is maintained by mechanical stimulation and depleted during aging.
Determining the mechanism of gene function is greatly enhanced using conditional mutagenesis. However, generating engineered conditional alleles is inefficient and has only been widely used in mice. Importantly, multiplex conditional mutagenesis requires extensive breeding. Here we demonstrate a system for one-generation multiplex conditional mutagenesis in zebrafish (Danio rerio) using transgenic expression of both cas9 and multiple single guide RNAs (sgRNAs). We describe five distinct zebrafish U6 promoters for sgRNA expression and demonstrate efficient multiplex biallelic inactivation of tyrosinase and insulin receptor a and b, resulting in defects in pigmentation and glucose homeostasis. Furthermore, we demonstrate temporal and tissue-specific mutagenesis using transgenic expression of Cas9. Heat-shock-inducible expression of cas9 allows temporal control of tyr mutagenesis. Liver-specific expression of cas9 disrupts insulin receptor a and b, causing fasting hypoglycemia and postprandial hyperglycemia. We also show that delivery of sgRNAs targeting ascl1a into the eye leads to impaired damage-induced photoreceptor regeneration. Our findings suggest that CRISPR/Cas9-based conditional mutagenesis in zebrafish is not only feasible but rapid and straightforward.KEYWORDS CRISPR/Cas9; conditional mutagenesis; glucose homeostasis; retinal regeneration; zebrafish C ONDITIONAL gene inactivation is necessary for determining physiological functions of genes whose conventional mutation causes embryonic lethality or multiorgan defects. It has been widely used in mice because of the availability of embryonic stem (ES) cells and large collections of both ES cell lines and animals that carry conditional alleles. The conditional alleles usually contain strategically placed Cre or Flp target sites in introns that permit deletion of the intervening exon(s) (Gu et al. 1994). Some conditional alleles harbor a Cre and/or Flp invertible gene trap in an intron that allows an on/off switch of transcription (Schnutgen et al. 2005;Ni et al. 2012). The function or expression of these alleles is "switched" off in the presence of Cre or Flp activity. In Drosophila, conditional gene inactivation can be achieved using RNA interference (RNAi), and genome-wide libraries of RNAi transgenes are available (Dietzl et al. 2007;Ni et al. 2008). For the increasingly popular zebrafish model, however, only limited conditional alleles generated from invertible gene trapping are available (Ni et al. 2012). The lack of ES cells and the inefficiency of RNAi in zebrafish necessitate new approaches for targeted conditional gene inactivation.CRISPR/Cas9 mutagenesis has been applied to many model systems from cultured cells to whole organisms (Doudna and Charpentier 2014;Hsu et al. 2014). The system only requires a two-component RNA-protein complex (RNP): a single guide RNA (sgRNA) that identifies the target through base pairing and the Cas9 endonuclease that generates double-strand breaks (DSBs) at the target site upon sgRNA-target base pairing. CRI...
SUMMARYUnlike the adult mammalian retina, Müller glia (MG) in the adult zebrafish retina are able to dedifferentiate into a ‘‘stem cell’’-like state and give rise to multipotent progenitor cells upon retinal damage. We show that miR-216a is downregulated in MG after constant intense light lesioning and that miR-216a suppression is necessary and sufficient for MG dedifferentiation and proliferation during retina regeneration. miR-216a targets the H3K79 methyltransferase Dot1l, which is upregulated in proliferating MG after retinal damage. Loss-of-function experiments show that Dot1l is necessary for MG reprogramming and mediates MG proliferation downstream of miR-216a. We further demonstrate that miR-216a and Dot1l regulate MG-mediated retina regeneration through canonical Wnt signaling. This article reports a regulatory mechanism upstream of Wnt signaling during retina regeneration and provides potential targets for enhancing regeneration in the adult mammalian retina.
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