Project description:Regulation of spatiotemporal gene expression in higher eukaryotic cells is critical for the precise and orderly development of undifferentiated progenitors into committed cell types of the adult. Recently, dynamic epigenomic regulation, including chromatin remodeling and histone modifications by transcriptional coregulator complexes, has been shown to be involved in transcriptional regulation. Precisely how these coregulator complexes exert their cell-type and developing stage-specific activity is largely unknown. In this study, we aimed to isolate the histone demethylase LSD1 complex from neural cells by biochemical purification. In so doing, we identified MyT1 as a novel LSD1 complex component. MyT1 is a neural cell-specific zinc finger factor and it forms a stable multiprotein complex with LSD1 through direct interaction. Target gene analysis using microarray and ChIP assays revealed several genes, including PTEN, that were directly regulated by the LSD1-MyT1 complex. Knockdown of either LSD1 or MyT1 derepressed the expression of endogenous target genes and inhibited cell proliferation of a neuroblastoma cell line, Neuro2a. We propose that formation of tissue-specific combinations of coregulator complexes is a critical mechanism for tissue-specific transcriptional regulation. Neuro2a cells were treated with either siControl, siLSD1 or siMyT1 for 48 h (n=3)

Project description:Here we performed a ChIP-seq experiment on a sample of adherent cultures of mouse neural stem cells (NS5 cell line) expressing an inducible HA-tagged version of the proneural factor MyT1 (MyT1-HA, under TetON control) after activation by doxycycline hyclate (DOX). This resulted in the generation of a genome-wide map of MyT1-HA binding to chromatin.

Project description:Identification of Myt1 as a subunit of the neural cell type-specific LSD1 complex

Project description:Here we performed a microarray experiment on samples of adherent cultures of mouse neural stem cells (NS5 cell line) expressing an inducible version of the transcription factor MyT1 (MyT1-V5 TetON) under normal growth conditions and after 4 hours of treatment by doxycyline. This resulted in the generation of a genome-wide mRNA expression pattern and quantification for these cells in the two conditions.

Project description:We report the changes in gene expression in U87 glioblastoma cells with re-introduced Myt1 or Myt1l.

Project description:Identification of Myt1 as a subunit of the neural cell type-specific LSD1 complex

Project description:Cellular differentiation requires both activation of target cell programs and repression of non-target cell programs. Transcriptional repressors such as RE1-silencing transcription factor (REST) and Hairy/Enhancer of Split (Hes) repress neuronal genes in non-neuronal cells. However, it is unknown whether transcriptional repressors of non-neuronal genes in neuronal precursors are required to specify neuronal fate during development. The Myt1 family of zinc finger transcription factors contributes to fibroblast to neuron reprogramming in vitro by repressing Notch signaling. Here, we show that ztf-11 (Zinc-finger Transcription Factor-11), the sole Caenorhabditis elegans Myt1 homolog, is required for neurogenesis in multiple neuronal lineages, including an in vivo developmental epithelial-to-neuronal transdifferentiation event. ztf-11 is exclusively expressed in all neuronal precursors with remarkable specificity at single cell resolution. Loss of ztf-11 leads to upregulation of non-neuronal genes and reduced neurogenesis. Ectopic expression of ztf-11 in epidermal lineages is sufficient to produce additional neurons. Our genetic and genomic experiments show that ZTF-11 indeed functions as a transcriptional repressor to suppress the activation of non-neuronal genes in neurons; however, it does not function via repression of Notch signaling. Instead, ZTF-11 binds to the MuvBco-repressor complex, which we show is also required for neurogenesis. These results dovetail with ability of Myt1l (Myt1-like) to drive neuronal transdifferentiation in vitro in vertebrate systems. Together, we identified an evolutionarily conserved mechanism to specify neuronal cell fate by repressing non-neuronal genes.

Project description:Precise control of transcriptional programs underlying metazoan development is modulated by enzymatically active co-regulatory complexes, coupled with epigenetic strategies, but how specific members of histone modification enzyme families such as histone methyltransferases and demethylases are utilized in vivo to simultaneously orchestrate distinct developmental gene activation and repression programs remains unclear. Here, we report that the initially-described histone lysine demethylase, LSD1, a component of the CoREST/CtBP corepressor complex, is required for late cell-lineage determination and differentiation during pituitary organogenesis. Surprisingly, LSD1 acts primarily on target gene activation programs, as well as in gene repression programs, based on recruitment of distinct LSD1-containing coactivator or corepressor complexes. Intriguingly, LSD1-dependent gene repression programs can be extended late in development with the induced expression of ZEB1, a Kr.pple-like repressor that can act as a molecular beacon for recruitment of the LSD1-containing CtBP/CoREST corepressor complex, causing repression of an additional cohort of genes, such as GH, that previously required LSD1 for activation.

Project description:This study first reveals that MYT1 is a potential oncogene in neuroblastoma, which is significantly correlated with poor prognosis and represses cellular differentiation via interrupting retinoic acid signaling pathway.

Project description:ChIP-Seq MyT1-HA in NS5