Luísa de Andrés-Aguayo scite author profile

The differentiation potential of T lineage cells becomes restricted soon after entry of multipotent precursors into the thymus and is accompanied by a downregulation of the transcription factors C/EBP alpha and PU.1. To investigate this restriction point, we have expressed C/EBP alpha and PU.1 in fully committed pre-T cells and found that C/EBP alpha (and C/EBP beta) induced the formation of functional macrophages. In contrast, PU.1 converted them into myeloid dendritic cells under identical culture conditions. C/EBP alpha-induced reprogramming is complex because upregulation of some but not all myelomonocytic markers required endogenous PU.1. Notch signaling partially inhibited C/EBP alpha-induced macrophage formation and completely blocked PU.1-induced dendritic cell formation. Likewise, expression of intracellular Notch or the transcription factor GATA-3 inhibited C/EBP alpha-induced lineage conversion. Our data show that committed T cell progenitors remain susceptible to the lineage instructive effects of myeloid transcription factors and suggest that Notch signaling induces T lineage restriction by downregulating C/EBP alpha and PU.1 in multilineage precursors.

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Tissue-specific control of brain-enriched miR-7 biogenesis

Choudhury

et al. 2013

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MicroRNA (miRNA) biogenesis is a highly regulated process in eukaryotic cells. Several mature miRNAs exhibit a tissue-specific pattern of expression without an apparent tissue-specific pattern for their corresponding primary transcripts. This discrepancy is suggestive of post-transcriptional regulation of miRNA abundance. Here, we demonstrate that the brain-enriched expression of miR-7, which is processed from the ubiquitous hnRNP K pre-mRNA transcript, is achieved by inhibition of its biogenesis in nonbrain cells in both human and mouse systems. Using stable isotope labeling by amino acids in cell culture (SILAC) mass spectrometry combined with RNase-assisted RNA pull-down, we identified Musashi homolog 2 (MSI2) and Hu antigen R (HuR) proteins as inhibitors of miR-7 processing in nonneural cells. This is achieved through HuR-mediated binding of MSI2 to the conserved terminal loop of pri-miR-7. Footprinting and electrophoretic gel mobility shift analysis (EMSA) provide further evidence for a direct interaction between pri-miR-7-1 and the HuR/MSI2 complex, resulting in stabilization of the pri-miR-7-1 structure. We also confirmed the physiological relevance of this inhibitory mechanism in a neuronal differentiation system using human SH-SY5Y cells. Finally, we show elevated levels of miR-7 in selected tissues from MSI2 knockout (KO) mice without apparent changes in the abundance of the pri-miR-7 transcript. Altogether, our data provide the first insight into the regulation of brain-enriched miRNA processing by defined tissue-specific factors.

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Musashi 2 is a regulator of the HSC compartment identified by a retroviral insertion screen and knockout mice

Andrés-Aguayo

Varas

Kallin

et al. 2011

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Single cell RNA-seq identifies the origins of heterogeneity in efficient cell transdifferentiation and reprogramming

Francesconi

Stefano

Berenguer

et al. 2019

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Forced transcription factor expression can transdifferentiate somatic cells into other specialised cell types or reprogram them into induced pluripotent stem cells (iPSCs) with variable efficiency. To better understand the heterogeneity of these processes, we used single-cell RNA sequencing to follow the transdifferentation of murine pre-B cells into macrophages as well as their reprogramming into iPSCs. Even in these highly efficient systems, there was substantial variation in the speed and path of fate conversion. We predicted and validated that these differences are inversely coupled and arise in the starting cell population, with Mychigh large pre-BII cells transdifferentiating slowly but reprogramming efficiently and Myclow small pre-BII cells transdifferentiating rapidly but failing to reprogram. Strikingly, differences in Myc activity predict the efficiency of reprogramming across a wide range of somatic cell types. These results illustrate how single cell expression and computational analyses can identify the origins of heterogeneity in cell fate conversion processes.

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Fibroblast-Derived Induced Pluripotent Stem Cells Show No Common Retroviral Vector Insertions

Varas

Stadtfeld

Andrés-Aguayo

et al. 2009

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Several laboratories have reported the reprogramming of mouse and human fibroblasts into pluripotent cells, using retroviruses carrying the Oct4, Sox2, Klf4, and c-Myc transcription factor genes. In these experiments the frequency of reprogramming was lower than 0.1% of the infected cells, raising the possibility that additional events are required to induce reprogramming, such as activation of genes triggered by retroviral insertions. We have therefore determined by ligation-mediated polymerase chain reaction (LM-PCR) the retroviral insertion sites in six induced pluripotent stem (iPS) cell clones derived from mouse fibroblasts. Seventy-nine insertion sites were assigned to a single mouse genome location. Thirty-five of these mapped to gene transcription units, whereas 29 insertions landed within 10 kilobases of transcription start sites. No common insertion site was detected among the iPS clones studied. Moreover, bioinformatics analyses revealed no enrichment of a specific gene function, network, or pathway among genes targeted by retroviral insertions. We conclude that Oct4, Sox2, Klf4, and c-Myc are sufficient to promote fibroblast-to-iPS cell reprogramming and propose that the observed low reprogramming frequencies may have alternative explanations.

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