Project description:The anterior pituitary-specific transcription factor POU1F1 (also called PIT-1) was initially identified and cloned as a transactivator of PRL, GH and TSHß subunit genes. Different studies indicated that POU1F1 could also have other functions in these cells. The identification of new targets of this factor could be useful to obtain a better understanding of these functions. Gene expression microarray assays were used to detect genes that have their expression modified in somatolactotrope GH4C1 cells by the expression of a dominant negative form of POU1F1, POU1F1(R271W).

Project description:The anterior pituitary-specific transcription factor POU1F1 (also called PIT-1) was initially identified and cloned as a transactivator of PRL, GH and TSHß subunit genes. Different studies indicated that POU1F1 could also have other functions in these cells. The identification of new targets of this factor could be useful to obtain a better understanding of these functions. Gene expression microarray assays were used to detect genes that have their expression modified in somatolactotrope GH4C1 cells by the expression of a dominant negative form of POU1F1, POU1F1(R271W). Lentiviral vectors containing the transgene of interest under the control of the PGK promoter (pGK-POU1F1(R271W)-IRES-EGFP, or pGK-EGFP used as controls) were generated. After lentiviral transfer in GH4C1 cells were grown in regular medium for 4 days then cells were harvested and total RNA was purified.

Project description:Transcripts regulated by Musashi-1 (MSI1) are explored through shRNA-mediated knockdown of MSI1 in SU_MB002 medulloblastoma cells.

Project description:mRNA-seq and ribosome profiling of neural stem cells overexpressing or knocked out for Musashi RNA-binding proteins Study of the global effects of Musashi (Msi) proteins on the transcriptome of embryonic neural stem cells. Neural stem cells were derived from brains of E12.5 or E13.5 embryos engineered to have inducible Msi1 or Msi2 genes, or from embryos with double floxed alleles of Msi1 and Msi2 carrying a Tamoxifen-induclble Cre (CreER). The overexpression mice were made using the Flp-in system (OpenBioSystems), where a cDNA of interest (in this case Msi1 or Msi2) is knocked into the Collagen (Col1A1) locus. The expression of the cDNA of interest is driven by m2rTTA that is knocked into the Rosa26 locus (R26). KH2 describes a strain containing the R26-m2rTTA but lacking Msi1 or Msi2 cDNA. MSI1 describes a strain containing R26-m2rTTA and Msi1 cDNA in Col1A1. MSI2 describes a strain containing R26-m2rTTA and Msi2 cDNA in Col1A1. C1 describes a strain lacking the CreER allele but containing double floxed alleles of Msi1/Msi2 (used as Tamoxifen control). C4 describes a strain carrying the CreER allele and double floxed alleles of Msi1/Msi2.

Project description:The anterior pituitary is comprised of distinct cell types that each secrete specific hormones to control a variety of biological processes including growth, metabolism, reproduction and stress responses. The anterior pituitary shows a remarkable level of cell type plasticity that allows shifts in hormone producing populations to meet organismal demands. Pituitary cell plasticity is tightly regulated and both deficiency in cell plasticity and excessive cell plasticity are associated with common pituitary pathologies. The molecular mechanisms underlying this plasticity are not well characterized but recent work has implicated the stem cell determinants and sequence-specific mRNA binding proteins of the Musashi family as regulators of adult pituitary hormone production. In this study we have sought to identify the full range of Musashi target mRNAs in the adult mouse pituitary. Using Musashi RNA immunoprecipitation we identify a cohort of 1192 mRNAs that show specific Musashi binding. These include mRNAs restricted to discrete hormone-producing cell lineages as well as mRNAs associated with stem and progenitor cells. The processes influenced by the proteins encoded by the Musashi-associated mRNAs include cellular homeostasis, protein trafficking and secretion, unfolded protein response, endocrine processes and female pregnancy. Functional analysis of validated mRNA regulatory 3' untranslated regions (3’ UTRs) reveals UTR-specific positive or negative control by the Musashi proteins within the same cellular context. Together, our findings indicate a broad role for Musashi proteins in the control of pituitary function.

Project description:The differentiation of the hormone-producing cell lineages of the anterior pituitary represents an informative model of mammalian cell fate determination. The generation and maintenance of two of these lineages, the growth hormone (GH) producing somatotropes and prolactin (PRL) producing lactotropes, is dependent on the pituitary-specific POU-homeo domain transcription factor, POU1F1. While POU1F1 is expressed in both cell types, and plays a direct and essential role in the activation of both the Gh and Prl genes, GH expression is restricted to somatotropes and PRL expression is restricted to lactotropes. These observations imply the existence of additional, cell type-enriched factors, that contribute to the somatotrope and lactotrope cell identities. Here, we use a set of transgenic mouse models to facilitate sorting of somatotrope and lactotrope populations based on the expression of distinct fluorescent markers expressed under Gh and Prl gene transcriptional controls, respectively. The transcriptomic analyses reveal a concordance of gene expression profiles in the two populations. The limited number of divergent mRNAs between the two populations includes a set of transcription factors that may have roles in pituitary lineage divergence or in regulating the expression of key lineage-specific genes after lineage divergence. Four of these factors were validated for lineage enrichment at the level of protein expression, two somatotrope-enriched and two lactotrope-enriched, and three of these four factors were shown to have corresponding activities in appropriate enhancement or repression of landmark genes. These studies establish a useful database for further study of the somatotrope and lactotrope cells as well as identify novel regulators of lineage marker expression in the anterior pituitary.

Project description:The Musashi family of mRNA translational regulators control both physiological and pathological stem cell self-renewal primarily by repressing targets that promote differentiation. In response to differentiation cues, Musashi can switch from a repressor to an activator of target mRNA translation. However, the molecular events that distinguish Musashi-mediated translational activation from repression are not understood. We have previously reported that Musashi function is required for the maturation of Xenopus oocytes, and specifically for translational activation of specific dormant maternal mRNAs. Here, we employed mass spectrometry to identify cellular factors necessary for Musashi-dependent mRNA translational activation. We report a requirement for association of Musashi1 with the embryonic poly(A) binding protein (ePABP) or the canonical somatic cell poly(A) binding protein PABPC1 for activation of Musashi target mRNA translation. Co-immunoprecipitation studies demonstrated an increased Musashi1 interaction with ePABP during oocyte maturation. Attenuation of endogenous ePABP activity severely compromised Musashi function, preventing downstream signaling and blocking oocyte maturation. Recovery of Musashi-dependent mRNA translational activation and maturation of ePABP attenuated oocytes was achieved through ectopic expression of either ePABP or PABPC1. Consistent with the findings in Xenopus oocytes, PABPC1 remained associated with Musashi under conditions of Musashi target mRNA de-repression and translation during mammalian stem cell differentiation. Since association of Musashi1 with poly(A) binding proteins has previously only been implicated in repression of Musashi target mRNAs, our findings reveal distinct context-dependent roles for the interaction of Musashi with poly[A] binding protein family members in response to extracellular cues that control cell fate.

Project description:POU1F1 regulates, in the pituitary, the development of the prolactin-, growth hormone- and thyrotropin ß-expressing lineages and the expression of these hormone in the mature pituitary through the direct regulation of their promoters. Besides these functions, POU1F1 is also involved in other cellular processes in the pituitary, such as cell division and survival, but the genomic targets involved in these actions are not known. The present ChIP-chip study identified a large number of hitherto unknown potential direct targets that might be involved in these actions, such as Tcf4, Lmo4, Pax6, Trp53 etc. ChIP-chip was done from pregnant female mouse (C57Bl/6J) pituitary (3 pools of 12 pituitary anterior lobes, corresponding to three biological replicates) with POU1F1 (PIT-1)

Project description:Transcripts bound to Musashi-1 (MSI1) are explored in Group 3 medulloblastoma (G3 MB) and neural stem cells harvested from the cerebellar portion of a embryonal brain

Project description:POU1F1 regulates, in the pituitary, the development of the prolactin-, growth hormone- and thyrotropin ß-expressing lineages and the expression of these hormone in the mature pituitary through the direct regulation of their promoters. Besides these functions, POU1F1 is also involved in other cellular processes in the pituitary, such as cell division and survival, but the genomic targets involved in these actions are not known. The present ChIP-chip study identified a large number of hitherto unknown potential direct targets that might be involved in these actions, such as Tcf4, Lmo4, Pax6, Trp53 etc.