Project description:The brassinosteroid (BR) phytohormone is an important regulator of plant growth. To identify novel transcription factors that regulate BR responses, we screened chimeric repressor gene silencing technology (CRES-T) plants, in which transcription factors were converted into chimeric repressors by the fusion of SRDX plant-specific repression domain, with brassinazole (Brz), an inhibitor of BR biosynthesis. We identified that a line that expressed the chimeric repressor for zinc finger homeobox transcription factor, BRASSINOSTEORID-RELATED-HOMEOBOX-2 (BHB2-sx), exhibited Brz-hypersensitive phenotype with shorter hypocotyl under dark, dwarf and round and dark green leaves similar to BR-deficient phenotype. Similar to BHB2-sx plants, bhb2 knockout mutant also exhibited Brz hypersensitive phenotype. In contrast, ectopic expression of BHB2 (BHB2-ox) showed hypocotyl elongation phenotype (BR excessive), showing decrease to Brz sensitivity. The expression of the DWF4 and CPD BR biosynthesis genes was repressed in BHB2-sx plants, whereas it was enhanced in BHB2-ox plants. The BR deficient-like phenotype of BHB2-sx plants was partially restored by treatment with brassinolide (BL), indicating that the BR deficient phenotype of BHB2-sx plant may be due to suppression of BR biosynthesis. Our results indicate that BHB2 is a positive regulator of BR response may be due to the promotion of BR biosynthesis genes.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Members of the Myt (myelin transcription factor) family have been implicated in neuronal development. However, their in vivo roles in OL lineage development have not been systematically investigated. Here, we identified Myt1 transcription factor as a crucial regulator of oligodendrocyte differentiation in the developing central nervous system. Conventional knockout of Myt1 causes a remarkable delay in the initiation of OL differentiation, without affecting the generation and proliferation of OPCs. Conversely, hyperactivation of Myt1 induces precocious OL differentiation both in vitro and in vivo. Using a combination of RNA-seq and ChIP-seq analyses, we identified Nkx2.2 as a key target of Myt1 to switch on the OL differentiation program. Mechanistically, specific binding of Myt1 in the Nkx2.2 gene loci inhibits the nucleosomal histone deacetylation via hindering the HDAC1 repressor complex integrity and reducing the deacetylation activity of HDAC1. Additionally, we demonstrated that Myt1 functions downstream of Notch signaling pathway in controlling the timing of OL differentiation. Collectively, our data demonstrate that Myt1 is a major regulator of OL differentiation and provide insight into the epigenetic regulatory mechanisms under OL development. Myt1 is, therefore, a promising therapeutic target for enhancing the OL differentiation and myelination/remyelination during development or after demyelination insults.

Project description:Members of the Myt (myelin transcription factor) family have been implicated in neuronal development. However, their in vivo roles in OL lineage development have not been systematically investigated. Here, we identified Myt1 transcription factor as a crucial regulator of oligodendrocyte differentiation in the developing central nervous system. Conventional knockout of Myt1 causes a remarkable delay in the initiation of OL differentiation, without affecting the generation and proliferation of OPCs. Conversely, hyperactivation of Myt1 induces precocious OL differentiation both in vitro and in vivo. Using a combination of RNA-seq and ChIP-seq analyses, we identified Nkx2.2 as a key target of Myt1 to switch on the OL differentiation program. Mechanistically, specific binding of Myt1 in the Nkx2.2 gene loci inhibits the nucleosomal histone deacetylation via hindering the HDAC1 repressor complex integrity and reducing the deacetylation activity of HDAC1. Additionally, we demonstrated that Myt1 functions downstream of Notch signaling pathway in controlling the timing of OL differentiation. Collectively, our data demonstrate that Myt1 is a major regulator of OL differentiation and provide insight into the epigenetic regulatory mechanisms under OL development. Myt1 is, therefore, a promising therapeutic target for enhancing the OL differentiation and myelination/remyelination during development or after demyelination insults.

Project description:The GATA-type zinc finger transcription factor TRPS1 has been implicated in breast cancer. However, its precise role remains unclear, as both amplifications and inactivating mutations in TRPS1 have been reported. Here, we used in vitro and in vivo loss-of-function approaches to dissect the role of TRPS1 in mammary gland development and invasive lobular breast carcinoma, which is hallmarked by functional loss of E-cadherin. We show that TRPS1 is essential in mammary epithelial cells, since TRPS1-mediated suppression of interferon signaling promotes in vitro proliferation and lactogenic differentiation. Similarly, TRPS1 expression is indispensable for proliferation of mammary organoids and in vivo survival of luminal epithelial cells during mammary gland development. However, the consequences of TRPS1 loss are dependent on E-cadherin status, as combined inactivation of E-cadherin and TRPS1 causes persistent proliferation of mammary organoids and accelerated mammary tumor formation in mice. Together, our results demonstrate that TRPS1 can function as a context-dependent tumor suppressor in breast cancer, while being essential for growth and differentiation of normal mammary epithelial cells.

Project description:Fetal Alz-50 clone 1 (FAC1) is a novel, developmentally regulated gene that exhibits changes in protein expression and subcellular localization during neuronal development and neurodegeneration. To understand the functional implications of altered subcellular localization, we have established a normal cellular function of FAC1. The FAC1 amino acid sequence contains regional homology to transcriptional regulators. Using the polymerase chain reaction-assisted binding site selection assay, we have identified a DNA sequence recognized by recombinant FAC1. Mutation of any 2 adjacent base pairs in the identified binding site dramatically reduced the binding preference of FAC1, demonstrating that the binding is specific for the identified site. Nuclear extracts from neural and non-neural cell lines contained a DNA-binding activity with similar specificity and nucleotide requirements as the recombinant FAC1 protein. This DNA-binding activity can be attributed to FAC1 since it is dependent upon the presence of FAC1 and behaves identically on a nondenaturing polyacrylamide gel as transiently transfected FAC1. In NIH3T3 cells, luciferase reporter plasmids containing the identified binding site (CACAACAC) were repressed by cotransfected FAC1 whether the binding site was proximal or distal to the transcription initiation site. This study indicates that FAC1 is a DNA-binding protein that functions as a transcription factor when localized to the nucleus.

Project description:Members of the Myt (myelin transcription factor) family have been implicated in neuronal development. However, their in vivo roles in OL lineage development have not been systematically investigated. Here, we identified Myt1 transcription factor as a crucial regulator of oligodendrocyte differentiation in the developing central nervous system. Conventional knockout of Myt1 causes a remarkable delay in the initiation of OL differentiation, without affecting the generation and proliferation of OPCs. Conversely, hyperactivation of Myt1 induces precocious OL differentiation both in vitro and in vivo. Using a combination of RNA-seq and ChIP-seq analyses, we identified Nkx2.2 as a key target of Myt1 to switch on the OL differentiation program. Mechanistically, specific binding of Myt1 in the Nkx2.2 gene loci inhibits the nucleosomal histone deacetylation via hindering the HDAC1 repressor complex integrity and reducing the deacetylation activity of HDAC1. Additionally, we demonstrated that Myt1 functions downstream of Notch signaling pathway in controlling the timing of OL differentiation. Collectively, our data demonstrate that Myt1 is a major regulator of OL differentiation and provide insight into the epigenetic regulatory mechanisms under OL development. Myt1 is, therefore, a promising therapeutic target for enhancing the OL differentiation and myelination/remyelination during development or after demyelination insults.

Project description:Members of the Myt (myelin transcription factor) family have been implicated in neuronal development. However, their in vivo roles in OL lineage development have not been systematically investigated. Here, we identified Myt1 transcription factor as a crucial regulator of oligodendrocyte differentiation in the developing central nervous system. Conventional knockout of Myt1 causes a remarkable delay in the initiation of OL differentiation, without affecting the generation and proliferation of OPCs. Conversely, hyperactivation of Myt1 induces precocious OL differentiation both in vitro and in vivo. Using a combination of RNA-seq and ChIP-seq analyses, we identified Nkx2.2 as a key target of Myt1 to switch on the OL differentiation program. Mechanistically, specific binding of Myt1 in the Nkx2.2 gene loci inhibits the nucleosomal histone deacetylation via hindering the HDAC1 repressor complex integrity and reducing the deacetylation activity of HDAC1. Additionally, we demonstrated that Myt1 functions downstream of Notch signaling pathway in controlling the timing of OL differentiation. Collectively, our data demonstrate that Myt1 is a major regulator of OL differentiation and provide insight into the epigenetic regulatory mechanisms under OL development. Myt1 is, therefore, a promising therapeutic target for enhancing the OL differentiation and myelination/remyelination during development or after demyelination insults.

Project description:Classical C2H2 zinc finger proteins are among the most abundant transcription factors found in eukaryotes, and the mechanisms through which they recognize their target genes have been extensively investigated. In general, a tandem array of three fingers separated by characteristic TGERP links is required for sequence-specific DNA recognition. Nevertheless, a significant number of zinc finger proteins do not contain a hallmark three-finger array of this type, raising the question of whether and how they contact DNA. We have examined the multi-finger protein ZNF217, which contains eight classical zinc fingers. ZNF217 is implicated as an oncogene and in repressing the E-cadherin gene. We show that two of its zinc fingers, 6 and 7, can mediate contacts with DNA. We examine its putative recognition site in the E-cadherin promoter and demonstrate that this is a suboptimal site. NMR analysis and mutagenesis is used to define the DNA binding surface of ZNF217, and we examine the specificity of the DNA binding activity using fluorescence anisotropy titrations. Finally, sequence analysis reveals that a variety of multi-finger proteins also contain two-finger units, and our data support the idea that these may constitute a distinct subclass of DNA recognition motif.

Project description:Protein acetylation has been implicated in playing an important role during mitotic progression. Aurora B kinase is known to play a critical role in mitosis. However, whether Aurora B is regulated by acetylation is not known. Using IP with an anti-acetyl lysine antibody, we identified Aurora B as an acetylated protein in PC3 prostate cancer cells. Knockdown of HDAC3 or inhibiting HDAC3 deacetylase activity led to a significant increase (P<0.01 and P<0.05, respectively) in Aurora B acetylation as compared to siLuc or vehicle-treated controls. Increased Aurora B acetylation is correlated with a 30% reduction in Aurora B kinase activity in vitro and resulted in significant defects in Aurora B-dependent mitotic processes, including kinetochore-microtubule attachment and chromosome congression. Furthermore, Aurora B transiently interacts with HDAC3 at the kinetochore-microtubule interface of congressing chromosomes during prometaphase. This window of interaction corresponded with a transient but significant reduction (P=0.02) in Aurora B acetylation during early mitosis. Together, these results indicate that Aurora B is more active in its deacetylated state and further suggest a new mechanism by which dynamic acetylation/deacetylation acts as a rheostat to fine-tune Aurora B activity during mitotic progression.