Project description:Neurogenic astroglia-like cells of the prospective white matter (PWM) generate interneurons and astroglia during cerebellar development. However, the characterization of PWM subpopulations is still insufficient. Here we show that ACSA-2 (Astrocyte Cell Surface Antigen-2) is an intrinsic marker of astrocyte-committed precursors. In the developing cerebellum, the ontogeny of ACSA-2+ astrocytes revealed this epitope to be exclusively expressed by PWM cells. By contrast, in the adult brain, ACSA-2 is observed on parenchymal astrocytes, fibrous astrocytes of the white matter and at low level on Bergmann glia. In combination with GLAST, a marker for astroglia-like progenitors, we addressed the characteristics of neurogenic (ACSA-2-/GLAST+) and astrocyte-committed (ACSA-2+/GLAST+) precursors using transcriptomics and cell transplantation assays. Gene expression analyses identified major differences in genes related to the maturation status of astrocytes, their potential to generate interneurons and genes required for Bergmann glia specification. Transplantation assays further confirmed a divergent differentiation potential: ACSA-2+/GLAST+ cells, on the one side, differentiate into astrocytes and oligodendrocytes but not into Bergmann glia or neurons when transplanted into the neonatal cerebellum. On the other side, ACSA-2-/GLAST+ progenitors were able to generate interneurons and all the glial phenotypes. Moreover, ACSA-2-/GLAST+ progenitors even maintained the neurogenic potential when transplanted into the adult cerebellum. In conclusion, this work reports about ACSA-2, a marker for glial-restricted precursors of the PWM that in combination with GLAST enables for the discrimination and isolation of neurogenic and astrocyte-committed progenitors of the neonatal cerebellum.

Project description:Bergmann glial cells of the vertebrate cerebellum play essential roles in the development and maintenance of cerebellar structure and function. During development, Bergmann glia provide structural support to the expanding cerebellar anlage and also serve as guides for migrating neurons (granule cells). As the cerebellum matures, Bergmann glia become important in dendritic arborization, synapse maintenance and synaptic function. The molecular mechanisms underlying these diverse and important functions of Bergmann glia remain largely unknown. We used microarray analysis to examine global gene expression in individual Bergmann glial cells derived at P6 (a time of extensive neuronal migration and cerebellar growth) and at P30 (when cerebellar development is complete and Bergmann glia play important roles at synapses). After gentle dissociation of cerebellar tissue derived from mice expressing GFP under the GFAP gene promoter (GFAP-GFP mice) (Zhuo, L., et al., 1997, Developmental biology), single GFP-positive Bergmann glial cells were aspirated into microcapillary tubes. Amplified cDNAs were prepared from single cells using RT-PCR and hybridized to Affymetrix GeneChip Mouse Genome 430 2.0 expression arrays (one array per cell). Five P6 cells and five P30 cells were used to generate the data presented in this study.

Project description:Bergmann glial cells of the vertebrate cerebellum play essential roles in the development and maintenance of cerebellar structure and function. During development, Bergmann glia provide structural support to the expanding cerebellar anlage and also serve as guides for migrating neurons (granule cells). As the cerebellum matures, Bergmann glia become important in dendritic arborization, synapse maintenance and synaptic function. The molecular mechanisms underlying these diverse and important functions of Bergmann glia remain largely unknown. We used microarray analysis to examine global gene expression in individual Bergmann glial cells derived at P6 (a time of extensive neuronal migration and cerebellar growth) and at P30 (when cerebellar development is complete and Bergmann glia play important roles at synapses).

Project description:Yin Yang 1 sets up the stage for cerebellar astrocyte maturation

Project description:Identifying alterations in gene expression and biological pathways within three brain regions of astrocyte-specific YY1 conditional knockout mice

Project description:Cerebellar circuitry is critical for balance and motor control among a wide array of functions and largely consists of granule and Purkinje neurons. Bergmann glia in the cerebellum form distinct morphological structures that facilitate granule neuron migration during development and that maintain the cerebellar organization and functional integrity. At present, molecular control of the formation and morphogenesis of Bergmann glia remains obscure. In this study, we found that Zeb2 (a.k.a. Sip1 or Zfhx1b), a Mowat-Wilson syndrome-associated transcriptional regulator, is highly restricted to Bergmann glia and is essential for their development and maturation. The mice with Zeb2 ablation in the cerebellar neural progenitor exhibit dysgenesis of cerebellar cortical lamination and locomotion defects. Deletion of Zeb2 markedly reduced Bergmann glial proliferation, differentiation and the establishment of the normal radial scaffold, disrupting migration of granule cell progenitors from external to internal granular layers. Transcriptome profiling indicated that Zeb2 regulates multiple pathways including FGF and Notch signaling as well as axonal guidance cues including Netrin G2 and Gdf10 to control Bergmann glial development. Our data reveal that Zeb2 acts as a transcriptional integrator of diverse signaling pathways to regulate the formation and morphogenesis of Bergmann glia ensuring maintenance of cerebellar integrity, suggesting that Zeb2 dysfunction in Bergmann glia might contribute to motor deficits in Mowat-Wilson syndrome.

Project description:Yin Yang 1 (YY1) and Structural Maintenance of Chromosomes 3 (SMC3) are two critical chromatin structural factors that mediate long-distance enhancer-promoter interactions and promote developmentally regulated changes in chromatin architecture in hematopoietic stem/progenitor cells (HSPCs). While YY1 plays critical functions in maintaining hematopoietic stem cell (HSC) quiescence, SMC3 is required for proper lineage differentiation. However, many questions remain unanswered regarding how YY1 and SMC3 interact with each other and impact hematopoiesis. We found that YY1 physically interacts with SMC3 and co-occupies with SMC3 at a large cohort of promoters genome-wide, and YY1 deficiency deregulates the genetic network governing cell metabolism. YY1 occupies the Smc3 promoter and represses SMC3 expression in HSPCs. While deletion of one Smc3 allele partially restores HSC numbers and quiescence in YY1 knockout mice, HSC self-renewal remains defective. YY1 regulates HSC metabolic pathways and maintains proper intracellular reactive oxygen species (ROS) levels in HSCs, and this regulation is independent of YY1- SMC3 axis. Our results establish a distinct YY1-SMC3 axis and its impact on HSC quiescence, self-renewal and metabolism

Project description:Yin Yang 1 (YY1) and Structural Maintenance of Chromosomes 3 (SMC3) are two critical chromatin structural factors that mediate long-distance enhancer-promoter interactions and promote developmentally regulated changes in chromatin architecture in hematopoietic stem/progenitor cells (HSPCs). While YY1 plays critical functions in promoting hematopoietic stem cell (HSC) self-renewal and maintaining HSC quiescence, SMC3 is required for proper myeloid lineage differentiation. However, many questions remain unanswered regarding how YY1 and SMC3 interact with each other and impact hematopoiesis. We found that YY1 physically interacts with SMC3 and co-occupies with SMC3 at a large cohort of promoters genome-wide, and YY1 deficiency deregulates the genetic network governing cell metabolism. YY1 occupies the Smc3 promoter and represses SMC3 expression in HSPCs. YY1 regulates HSC metabolic pathways and maintains proper intracellular reactive oxygen species levels in HSCs, and this regulation is independent of YY1- SMC3 axis. Our results establish a distinct YY1-SMC3 axis and its impact on HSC quiescence and metabolism.

Project description:Yin Yang 1 (YY1) is a multifunctional transcription factor shown to be critical in a variety of biological processes. Although it has been reported to be regulated by multiple types of post-translational modifications (PTMs), whether YY1 is methylated, which enzyme methylates YY1, and hence the functional significance of YY1 methylation remain completely unknown. Here we reported the first methyltransferase, SET7/9 (KMT7), capable of methylating YY1 in vitro and in vivo at two highly conserved lysine (K) residues, K173 and K411, located in two distinct domains, one in the central glycine-rich region and the other in the very carboxyl-terminus. Functional study revealed that SET7/9-mediated YY1 methylation regulated YY1 DNA-binding activity both in vitro and at specific genomic loci in cultured cells. Consistently, SET7/9-mediated YY1 methylation was shown to involve in YY1-regulated gene transcription and cell proliferation. Our findings revealed a novel regulatory strategy, methylation by lysine methyltransferase, imposed on YY1 protein, and linked YY1 methylation with its biological functions.

Project description:Yin Yang 1 (YY1) is a multifunctional transcription factor shown to be critical in a variety of biological processes. Although it has been reported to be regulated by multiple types of post-translational modifications (PTMs), whether YY1 is methylated, which enzyme methylates YY1, and hence the functional significance of YY1 methylation remain completely unknown. Here we reported the first methyltransferase, SET7/9 (KMT7), capable of methylating YY1 in vitro and in vivo at two highly conserved lysine (K) residues, K173 and K411, located in two distinct domains, one in the central glycine-rich region and the other in the very carboxyl-terminus. Functional study revealed that SET7/9-mediated YY1 methylation regulated YY1 DNA-binding activity both in vitro and at specific genomic loci in cultured cells. Consistently, SET7/9-mediated YY1 methylation was shown to involve in YY1-regulated gene transcription and cell proliferation. Our findings revealed a novel regulatory strategy, methylation by lysine methyltransferase, imposed on YY1 protein, and linked YY1 methylation with its biological functions.