The bmi-1 gene was first isolated as an oncogene that cooperates with c-myc in the generation of mouse lymphomas. We subsequently identified Bmi-1 as a transcriptional repressor belonging to the mouse Polycomb group. The Polycomb group comprises an important, conserved set of proteins that are required to maintain stable repression of specific target genes, such as homeobox-cluster genes, during development. In mice, the absence of bmi-1 expression results in neurological defects and severe proliferative defects in lymphoid cells, whereas bmi-1 overexpression induces lymphomas. Here we show that bmi-1-deficient primary mouse embryonic fibroblasts are impaired in progression into the S phase of the cell cycle and undergo premature senescence. In these fibroblasts and in bmi-1-deficient lymphocytes, the expression of the tumour suppressors p16 and p19Arf, which are encoded by ink4a, is raised markedly. Conversely, overexpression of bmi-1 allows fibroblast immortalization, downregulates expression of p16 and p19Arf and, in combination with H-ras, leads to neoplastic transformation. Removal of ink4a dramatically reduces the lymphoid and neurological defects seen in bmi-1-deficient mice, indicating that ink4a is a critical in vivo target for Bmi-1. Our results connect transcriptional repression by Polycomb-group proteins with cell-cycle control and senescence.
Accumulation of the prion protein PrPSc, a pathological and protease-resistant isoform of the normal host protein PrPC, is a feature of prion disease such as scrapie. It is still unknown whether scrapie pathology comes about by neurotoxicity of PrPSc, acute depletion of PrPC, or some other mechanism. Here we investigate this question by grafting neural tissue overexpressing PrPC into the brain of PrP-deficient mice which are scrapie-resistant and do not propagate infectivity. After intracerebral inoculation with scrapie prions, the grafts accumulated high levels of PrPSc and infectivity and developed the severe histopathological changes characteristic of scrapie. Moreover, substantial amounts of graft-derived PrPSc migrated into the host brain. Even 16 months after inoculation no pathological changes were seen in PrP-deficient tissue, not even in the immediate vicinity of the grafts. Therefore, in addition to being resistant to scrapie infection, brain tissue devoid of PrPC is not damaged by exogenous PrPSc.
The development of the mammalian cerebellum is orchestrated by both cell-autonomous programs and inductive environmental influences. Here, we describe the main processes of cerebellar ontogenesis, highlighting the neurogenic strategies used by developing progenitors, the genetic programs involved in cell fate specification, the progressive changes of structural organization, and some of the better-known abnormalities associated with developmental disorders of the cerebellum.
Overexpression of the polycomb group gene Bmi1 promotes cell proliferation and induces leukaemia through repression of Cdkn2a (also known as ink4a/Arf) tumour suppressors. Conversely, loss of Bmi1 leads to haematological defects and severe progressive neurological abnormalities in which de-repression of the ink4a/Arf locus is critically implicated. Here, we show that Bmi1 is strongly expressed in proliferating cerebellar precursor cells in mice and humans. Using Bmi1-null mice we demonstrate a crucial role for Bmi1 in clonal expansion of granule cell precursors both in vivo and in vitro. Deregulated proliferation of these progenitor cells, by activation of the sonic hedgehog (Shh) pathway, leads to medulloblastoma development. We also demonstrate linked overexpression of BMI1 and patched (PTCH), suggestive of SHH pathway activation, in a substantial fraction of primary human medulloblastomas. Together with the rapid induction of Bmi1 expression on addition of Shh or on overexpression of the Shh target Gli1 in cerebellar granule cell cultures, these findings implicate BMI1 overexpression as an alternative or additive mechanism in the pathogenesis of medulloblastomas, and highlight a role for Bmi1-containing polycomb complexes in proliferation of cerebellar precursor cells.
The Polycomb group (PcG) gene Bmi1 promotes cell proliferation and stem cell self-renewal by repressing the Ink4a/Arf locus. We used a genetic approach to investigate whether Ink4a or Arf is more critical for relaying Bmi1 function in lymphoid cells, neural progenitors, and neural stem cells. We show that Arf is a general target of Bmi1, however particularly in neural stem cells, derepression of Ink4a contributes to Bmi1 −/− phenotypes. Additionally, we demonstrate haploinsufficient effects for the Ink4a/Arf locus downstream of Bmi1 in vivo. This suggests differential, cell type-specific roles for Ink4a versus Arf in PcG-mediated (stem) cell cycle control.Supplemental material is available at http://www.genesdev.org.
The highly homologous Rnf2 (Ring1b) and Ring1 (Ring1a) proteins were identified as in vivo interactors of the Polycomb Group (PcG) protein Bmi1. Functional ablation of Rnf2 results in gastrulation arrest, in contrast to relatively mild phenotypes in most other PcG gene null mutants belonging to the same functional group, among which is Ring1. Developmental defects occur in both embryonic and extraembryonic tissues during gastrulation. The early lethal phenotype is reminiscent of that of the PcG-gene knockouts Eed and Ezh2, which belong to a separate functional PcG group and PcG protein complex. This finding indicates that these biochemically distinct PcG complexes are both required during early mouse development. In contrast to the strong skeletal transformation in Ring1 hemizygous mice, hemizygocity for Rnf2 does not affect vertebral identity. However, it does aggravate the cerebellar phenotype in a Bmi1 nullmutant background. Together, these results suggest that Rnf2 or Ring1-containing PcG complexes have minimal functional redundancy in specific tissues, despite overlap in expression patterns. We show that the early developmental arrest in Rnf2-null embryos is partially bypassed by genetic inactivation of the Cdkn2a (Ink4a͞ARF) locus. Importantly, this finding implicates Polycomb-mediated repression of the Cdkn2a locus in early murine development. P olycomb Group (PcG) proteins and their genetic counterparts, the trithorax Group proteins (trxG), maintain Hox gene expression boundaries (1-4), which are critical for regional patterning along the antero-posterior (AP) axis (5-7). Based on biochemical characteristics, mammalian PcG proteins are currently grouped into at least two distinct functional groups: the first comprises Eed, Ezh1, and Ezh2 in the mouse (8, 9); the second consists of the highly related protein pairs Cbx2 (M33)͞Cbx4 (MPc2), Bmi͞Zfp144 (Mel18), and Edr1 and 2 (Rae28͞Mph1 and 2), respectively (10, 11). For ease of this discussion we refer to them as groups I and II, respectively. Group I and II homologs are evolutionarily conserved from Drosophila to humans, only group I homologs are found in plants and Caenorhabditis elegans as well, supporting the concept of separate function (12, 13). In addition, complex composition differs throughout development in a temporal and cell-type-specific manner (14, 15). Interaction of Eed with histone deacetylases and the intrinsic histone methyltransferase activity of Ezh proteins suggest mechanisms for repression by group I complexes (16)(17)(18)(19). Although a mammalian hPRC-H (group II) complex harbors an intrinsic capacity to stabilize a repressive chromatin structure and counteract SWI͞SNF chromatin remodeling complexes in vitro, its in vivo mode of action is not well understood (20). Association with histone methyl transferase activity may in part help explain the repressive action of some group II complexes (21).Rnf2 and Ring1 have been identified as in vivo interactors of the group II PcG protein Bmi1 by us and others (22). These Ring finger proteins...
Studies in tissue culture cells have implicated p300 and CBP acetyltransferases in myogenic regulatory factor (MRF) mediated transcription and terminal differentiation of skeletal muscle cells. However, in vivo data placing p300 and CBP on myogenic differentiation pathways are not yet available. In this report we provide genetic evidence that p300 but not CBP acetyltransferase (AT) activity is required for myogenesis in the mouse and in embryonic stem (ES) cells. A fraction of embryos carrying a single p300 AT- deficient allele exhibit impaired MRF expression, delayed terminal differentiation and a reduced muscle mass. In mouse embryos lacking p300 protein, Myf-5 induction is severely attenuated. Similarly, ES cells homozygous for a p300 AT or a p300 null mutation fail to activate Myf5 and MyoD transcription efficiently, while Pax3, acting genetically upstream of these MRFs, is expressed. In contrast, ES cells lacking CBP AT activity express MyoD and Myf5 and undergo myogenic differentiation. These data reveal a specific requirement for p300 and its AT activity in the induction of MRF gene expression and myogenic cell fate determination in vivo.
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