Project description:This experiment was carried to identify potential reprogramming factors that augment Sall1 and Nanog reprogramming efficiency either individually or in combination during co-expression. The intent of the experiment was to understand genes regulated by Sall1 and Nanog during mouse epiblast stem cell reprogramming. Empty: mock transfected cells. Nanog: Nanog gene expressing plasmid. Sall1: Sall1 gene expressing plasmid. Untransfected: Untransfected cells. Sall1Nanog: Sall1 and Nanog expressing plasmids (cotransfection).

Project description:Members of the Nucleosome Remodeling and Deacetylase (NuRD) complex Mbd3 and Mi2beta (Chd4) along with pluripotency regulators Nanog, Oct4, Klf4 and Esrrb were profiled for chromatin association by ChIP-seq in mouse embryonic stem cells mutant for Mbd3, Sall4 and/or the related Sall1 pluripotency-associated factors.

Project description:Spalt-Like Transcription Factor 1 (Sall1) is a critical regulator of organogenesis and microglia identity. Despite its known biological importance, mechanisms that specify the cell-specific expression of Sall1 and its transcriptional functions remain poorly understood. Here, we demonstrate that targeted deletion of a conserved microglia-specific super enhancer interacting with the Sall1 promoter results in complete and specific loss of Sall1 expression in microglia, thereby identifying an essential regulatory element that transduces brain environmental signals required for microglia-specific gene expression. By determining the genomic binding sites of SALL1 and leveraging Sall1 enhancer knock out (EKO) mice to probe how SALL1 shapes the regulatory landscape of microglia, we provide evidence that SALL1 functions to both directly activate microglia-specific genes and repress genes that are associated with inflammation and aging. Unexpectedly, motifs for SMAD proteins that mediate transcriptional effects of TGFb signaling were enriched within the set of enhancers predicted to be directly activated by SALL1, suggesting that collaborative interactions between SALL1 and SMADs are required to establish microglia-specific gene expression. To test this hypothesis, we determined the transcriptional consequences of a conditional knockout of the common co-SMAD Smad4 and defined the genome-wide locations of SMAD4 in wild type and EKO microglia. These studies revealed two layers of functional interdependence. First, we found that SMAD4 binds directly to the Sall1 super enhancer and is required for Sall1 expression, consistent with the requirement of the TGFb and SMAD homologues Dpp and Mad for cell-specific expression of Spalt in the Drosophila wing. Second, we extend this paradigm by demonstrating that SALL1 in turn promotes binding and function of SMAD4 at microglia-specific enhancers while simultaneously suppressing binding of SMAD4 to enhancers of genes that become inappropriately activated in EKO microglia. Collectively, these results suggest molecular mechanisms by which SALL1 enforces microglia-specific functions of the TGFb-SMAD signaling axis that may be relevant to roles of SALL1 in other developmental contexts.

Project description:Spalt-Like Transcription Factor 1 (Sall1) is a critical regulator of organogenesis and microglia identity. Despite its known biological importance, mechanisms that specify the cell-specific expression of Sall1 and its transcriptional functions remain poorly understood. Here, we demonstrate that targeted deletion of a conserved microglia-specific super enhancer interacting with the Sall1 promoter results in complete and specific loss of Sall1 expression in microglia, thereby identifying an essential regulatory element that transduces brain environmental signals required for microglia-specific gene expression. By determining the genomic binding sites of SALL1 and leveraging Sall1 enhancer knock out (EKO) mice to probe how SALL1 shapes the regulatory landscape of microglia, we provide evidence that SALL1 functions to both directly activate microglia-specific genes and repress genes that are associated with inflammation and aging. Unexpectedly, motifs for SMAD proteins that mediate transcriptional effects of TGFb signaling were enriched within the set of enhancers predicted to be directly activated by SALL1, suggesting that collaborative interactions between SALL1 and SMADs are required to establish microglia-specific gene expression. To test this hypothesis, we determined the transcriptional consequences of a conditional knockout of the common co-SMAD Smad4 and defined the genome-wide locations of SMAD4 in wild type and EKO microglia. These studies revealed two layers of functional interdependence. First, we found that SMAD4 binds directly to the Sall1 super enhancer and is required for Sall1 expression, consistent with the requirement of the TGFb and SMAD homologues Dpp and Mad for cell-specific expression of Spalt in the Drosophila wing. Second, we extend this paradigm by demonstrating that SALL1 in turn promotes binding and function of SMAD4 at microglia-specific enhancers while simultaneously suppressing binding of SMAD4 to enhancers of genes that become inappropriately activated in EKO microglia. Collectively, these results suggest molecular mechanisms by which SALL1 enforces microglia-specific functions of the TGFb-SMAD signaling axis that may be relevant to roles of SALL1 in other developmental contexts.

Project description:Spalt-Like Transcription Factor 1 (Sall1) is a critical regulator of organogenesis and microglia identity. Despite its known biological importance, mechanisms that specify the cell-specific expression of Sall1 and its transcriptional functions remain poorly understood. Here, we demonstrate that targeted deletion of a conserved microglia-specific super enhancer interacting with the Sall1 promoter results in complete and specific loss of Sall1 expression in microglia, thereby identifying an essential regulatory element that transduces brain environmental signals required for microglia-specific gene expression. By determining the genomic binding sites of SALL1 and leveraging Sall1 enhancer knock out (EKO) mice to probe how SALL1 shapes the regulatory landscape of microglia, we provide evidence that SALL1 functions to both directly activate microglia-specific genes and repress genes that are associated with inflammation and aging. Unexpectedly, motifs for SMAD proteins that mediate transcriptional effects of TGFb signaling were enriched within the set of enhancers predicted to be directly activated by SALL1, suggesting that collaborative interactions between SALL1 and SMADs are required to establish microglia-specific gene expression. To test this hypothesis, we determined the transcriptional consequences of a conditional knockout of the common co-SMAD Smad4 and defined the genome-wide locations of SMAD4 in wild type and EKO microglia. These studies revealed two layers of functional interdependence. First, we found that SMAD4 binds directly to the Sall1 super enhancer and is required for Sall1 expression, consistent with the requirement of the TGFb and SMAD homologues Dpp and Mad for cell-specific expression of Spalt in the Drosophila wing. Second, we extend this paradigm by demonstrating that SALL1 in turn promotes binding and function of SMAD4 at microglia-specific enhancers while simultaneously suppressing binding of SMAD4 to enhancers of genes that become inappropriately activated in EKO microglia. Collectively, these results suggest molecular mechanisms by which SALL1 enforces microglia-specific functions of the TGFb-SMAD signaling axis that may be relevant to roles of SALL1 in other developmental contexts.

Project description:Spalt-Like Transcription Factor 1 (Sall1) is a critical regulator of organogenesis and microglia identity. Despite its known biological importance, mechanisms that specify the cell-specific expression of Sall1 and its transcriptional functions remain poorly understood. Here, we demonstrate that targeted deletion of a conserved microglia-specific super enhancer interacting with the Sall1 promoter results in complete and specific loss of Sall1 expression in microglia, thereby identifying an essential regulatory element that transduces brain environmental signals required for microglia-specific gene expression. By determining the genomic binding sites of SALL1 and leveraging Sall1 enhancer knock out (EKO) mice to probe how SALL1 shapes the regulatory landscape of microglia, we provide evidence that SALL1 functions to both directly activate microglia-specific genes and repress genes that are associated with inflammation and aging. Unexpectedly, motifs for SMAD proteins that mediate transcriptional effects of TGFb signaling were enriched within the set of enhancers predicted to be directly activated by SALL1, suggesting that collaborative interactions between SALL1 and SMADs are required to establish microglia-specific gene expression. To test this hypothesis, we determined the transcriptional consequences of a conditional knockout of the common co-SMAD Smad4 and defined the genome-wide locations of SMAD4 in wild type and EKO microglia. These studies revealed two layers of functional interdependence. First, we found that SMAD4 binds directly to the Sall1 super enhancer and is required for Sall1 expression, consistent with the requirement of the TGFb and SMAD homologues Dpp and Mad for cell-specific expression of Spalt in the Drosophila wing. Second, we extend this paradigm by demonstrating that SALL1 in turn promotes binding and function of SMAD4 at microglia-specific enhancers while simultaneously suppressing binding of SMAD4 to enhancers of genes that become inappropriately activated in EKO microglia. Collectively, these results suggest molecular mechanisms by which SALL1 enforces microglia-specific functions of the TGFb-SMAD signaling axis that may be relevant to roles of SALL1 in other developmental contexts.

Project description:Identification of downstream targets and pathways initiated by Sall1 and Nanog during reprogramming

Project description:Unique traits of pluripotent stem cells are not fully known. Using thermal proteome profiling, we identified reduced stability of ribosomes in induced pluripotent cells (iPSCs) compared to that in somatic cells. Also, iPSCs exhibited lower protein synthesis rate and lower expression of a ribosome maturation factor, the Shwachman-Bodian-Diamond Syndrome protein (SBDS). Differentiation of iPSCs led to upregulation of SBDS and knock-down of SBDS slowed the differentiation while increasing expression of master pluripotency markers NANOG and OCT4. Mutations in the SBDS gene have been shown to impair ribosome assembly and to inhibit differentiation of hematopoietic stem cells causing the Shwachman-Diamond syndrome. Physiological SBDS-dependent destabilization of ribosomes appears to be a tool for translational control providing robustness to the state of pluripotency.

Project description:Unique traits of pluripotent stem cells are not fully known. Using thermal proteome profiling, we identified reduced stability of ribosomes in induced pluripotent cells (iPSCs) compared to that in somatic cells. Also, iPSCs exhibited lower protein synthesis rate and lower expression of a ribosome maturation factor, the Shwachman-Bodian-Diamond Syndrome protein (SBDS). Differentiation of iPSCs led to upregulation of SBDS and knock-down of SBDS slowed the differentiation while increasing expression of master pluripotency markers NANOG and Oct-4. Mutations in the SBDS gene have been shown to impair ribosome assembly and to inhibit differentiation of hematopoietic stem cells causing the Shwachman- Diamond syndrome. Physiological SBDS-dependent destabilization of ribosomes appears to be a tool for translational control providing robustness to the state of pluripotency.

Project description:Mouse embryonic stem cells mutant for Mbd3, Sall4 and/or the related Sall1 pluripotency-associated factors were cultured in self-renewing and neural differentiation conditions and profiled by RNA-seq.