Stephen Iannaccone scite author profile

Development of stem and progenitor cells into specialized tissues in multicellular organisms involves a series of cell fate decisions. Cellular differentiation in higher organisms is generally considered irreversible, and the idea of developmental plasticity in postnatal tissues is controversial. Here, we show that inhibition of mitogenactivated protein kinase (MAPK) in a human bone marrow stromal cell-derived myogenic subclone suppresses their myogenic ability and converts them into satellite cell-like precursors that respond to osteogenic stimulation. Clonal analysis of the induced osteogenic response reveals ultrasensitivity and an ''all-or-none'' behavior, hallmarks of a bistable switch mechanism with stochastic noise. The response demonstrates cellular memory, which is contingent on the accumulation of an intracellular factor and can be erased by factor dilution through cell divisions or inhibition of protein synthesis. The effect of MAPK inhibition also exhibits memory and appears to be controlled by another bistable switch further upstream that determines cell fate. Once the memory associated with osteogenic differentiation is erased, the cells regain their myogenic ability. These results support a model of cell fate decision in which a network of bistable switches controls inducible production of lineage-specific differentiation factors. A competitive balance between these factors determines cell fate. Our work underscores the dynamic nature of cellular differentiation and explains mechanistically the dual properties of stability and plasticity associated with the process.bistability ͉ MAPK signaling ͉ mesenchymal progenitors ͉ myogenic differentiation ͉ osteogenic differentiation I n multicellular organisms, differentiated cells perform a wide range of specialized functions. Understanding how multipotent stem and progenitor cells develop into these differentiated cells is a central question in biology. Cellular differentiation is assumed to involve a series of cell fate decisions, each of which is generally considered irreversible in higher organisms. The irreversibility in differentiation contributes to phenotypic stability of the specialized cells, which enable them to perform their respective functions (1). Recent reports have demonstrated that differentiated cells can also exhibit an extraordinary degree of developmental plasticity. Transfer of specific pluripotency genes into somatic cells, for example, can convert them into stem cell-like cells that can differentiate into diverse tissues (2). It remains controversial whether plasticity occurs in postnatal tissues of higher organisms in a physiological context (3). It is likely that cellular differentiation possesses the dual properties of stability and plasticity, and either might predominate, depending on the environmental milieu.In recent years, the application of the systems-biology approach in biological studies has been extraordinarily fruitful (4). In this approach, the focus is on quantitative analysis of the interactions between individual...

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Defining a role for Sonic hedgehog pathway activation in desmoplastic medulloblastoma by identifying GLI1 target genes

Yoon

Gilbertson

Iannaccone

et al. 2008

Intl Journal of Cancer

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A subgroup of medulloblastomas shows constitutive activation of the Sonic hedgehog pathway with expression of GLI1. We identified the subset of GLI1 transforming target genes specifically expressed in medulloblastomas by comparing GLI1 targets in RK3E cells transformed by GLI1 with the gene expression profile of Sonic hedgehog signature medulloblastomas. We identified 1,823 genes whose expression was altered more than 2-fold in 2 independent RK3E + GLI1 cell lines. We identified 25 whose expression was altered similarly in medulloblastomas expressing GLI1. We identified potential GLI binding elements in the regulatory regions of 10 of these genes, confirmed that GLI1 binds the regulatory regions and activates transcription of select genes, and showed that GLI1 directly represses transcription of Krox-20. We identified upregulation of CXCR4, a chemokine receptor that plays roles in the proliferation and migration of granule cell neuron precursors during development, supporting the concept that reinitiation of developmental programs may contribute to medulloblastoma tumorigenesis. In addition, the targets suggest a pathway through which GLI1 may ultimately affect medulloblastoma cell proliferation, survival and genomic stability by converging on p53, SGK1, MGMT and NTRK2. We identify a p53 mutation in RK3E + GLI1 cells, suggesting that p53 mutations may sometimes shift the balance toward dysregulated tumor cell survival.

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Noncanonical Regulation of the Hedgehog Mediator GLI1 by c-MYC in Burkitt Lymphoma

Yoon

Gallant

Lamm

et al. 2013

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Although Hedgehog signaling plays a major role in GLI1 transcription, there is now evidence suggesting that other pathways/genes, such as c-MYC, may also regulate GLI1 expression. We initiated studies in Burkitt lymphoma cells, which constitutively express c-MYC due to a chromosomal translocation, to determine whether Hedgehog or c-MYC regulates GLI1 expression. We show that all Burkitt lymphoma cell lines tested express GLI1, PTCH1, and SMO and that five of six Burkitt lymphomas express GLI1. Exposure to Sonic or Indian Hedgehog or cyclopamine (SMO inhibitor) does not modulate GLI1 expression, cell proliferation, or apoptosis in most Burkitt lymphoma cell lines. Sequence analysis of PTCH1, SMO, and SuFu failed to show mutations that might explain the lack of Hedgehog responsiveness, and we did not detect primary cilia, which may contribute to it. We show that c-MYC interacts with the 5 0 -regulatory region of GLI1, using chromatin immunoprecipitation (ChIP) assay, and E-box-dependent transcriptional activation of GLI1 by c-MYC in NIH3T3 and HeLa cells. The c-MYC small-molecule inhibitor 10058-F4 downregulates GLI1 mRNA and protein and reduces the viability of Burkitt lymphoma cells.

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