Project description:In this study, we compare the DNA binding specifify and affinity of SEPALLATA3 and AGAMOUS complexes The MADS transcription factors, SEPALLATA3 (SEP3) and AGAMOUS (AG), are required for floral organ identity and determinacy of the floral meristem in Arabidopsis. Dimerization is obligatory for their DNA binding, however SEP3 and SEP3-AG also form tetrameric complexes. The goal of this study is to understand how homo and hetero-dimerization and tetramerization of MADS TFs affect genome-wide DNA-binding patterns. Using a modified sequential DNA affinity purification sequencing protocol (seq-DAP-seq), we selectively purified SEP3 homomeric and SEP3-AG heteromeric complexes, including the dimeric SEP3 tet-AG complex and the tetrameric SEP3-AG complex, and determined their genome-wide binding.

Project description:Genome-wide binding of SEPALLATA3 (SEP3) and AGAMOUS (AG) complexes determined by sequential DNA-affinity purification sequencing

Project description:With this experiment, our objective is to identify the binding sites of MADS-domain protein complexes and determine if they exhibit binding to different targets or with differing affinities, which could be a mechanism to acquire target gene specificity. Specifically, we aim to investigate this phenomenon for the tetramers FUL-SOC1 and FUL-AG-SEP3, as they are enriched in different tissues, thus likely regulating distinct functions. FUL-SOC1 is enriched in the inflorescence meristem, whereas the FUL-AG-SEP3 complex is enriched in the siliques. Using the DAP-seq protocol, we established their genome-wide binding profiles and included other FUL complexes (FUL, FUL-AG, and FUL-SEP3) as controls.

Project description:In this study, we applied sequential DNA affinity purification sequencing (seq-DAP-seq) to identiy genome-wide binding of a heterocomplex formed by two transcription factors of the MADS familly SEP3 and AG(AP1-I) (AG with its I domain switched with that of AP1). We compared the genome wide binding of SEP3-AG(AP1-I) to that of our previously published SEP3-AG data

Project description:The mechanism underlying CUC genes regulating leaf marginal patterning remains largely unknown. To this end, we employed DAP-seq to identify the downstream regulating genes of ChCUC1. The aim of this project is to map genome-wide CUC genes binding sites.

Project description:Chromatin immunoprecipitation coupled with ultra-high-throughput sequencing (ChIP-seq) is a widely used method for mapping the interactions of proteins with DNA. However, the requirements for ChIP-grade antibodies impede wider application of this method, and variations in results can be high owing to differences in affinity and cross-reactivity of antibodies. Therefore, we developed chromatin tandem affinity purification (ChTAP) as an effective alternative to ChIP. Through the use of affinity tags and reagents that are identical for all proteins investigated, ChTAP enables one to directly compare the binding between different transcription factors and to directly assess the background in control experiments. Thus, ChTAP-seq can be used to rapidly map the genome-wide binding of multiple DNA-binding proteins in a wide range of cell types. ChTAP can be completed in 3-4 d, starting from cross-linking of chromatin to purification of ChIP DNA.

Project description:In vitro assembly of translation initiation complexes from higher eukaryotes requires purification of ribosomal subunits, eukaryotic initiation factors, and initiator tRNA from natural sources, and therefore yields only limited material for functional and structural studies. Here we describe a robust, affinity chromatography-based purification of eukaryotic 48S initiation complexes from rabbit reticulocyte lysate (RRL), which significantly reduces the number of individual purification steps. Hybrid RNA molecules, consisting of either a canonical 5' UTR or an internal ribosome entry site (IRES) RNA followed by a short open reading frame and a streptomycin aptamer sequence, are incubated in RRL to form 48S complexes. The assembly reaction is then applied to a dihydrostreptomycin-sepharose column; bound complexes are washed and specifically eluted upon addition of streptomycin. The eluted fractions are further purified by centrifugation through a sucrose density gradient to yield pure 48S particles. Using this purification scheme, properly assembled IRES-mediated as well as canonical 48S complexes were purified in milligram quantities.

Project description:The MADS genes encode transcription factors (TF) that act as master regulators of plant reproduction and flower development. The SEPALLATA (SEP) MADS subfamily is not only absolutely required for the development of floral organs, but also plays roles in inflorescence architecture and determinacy of the floral meristem. The SEPs act as organizers of MADS complexes and are able to form both heterodimers and heterotetramers in vitro. To date, the MADS TF complexes characterized in angiosperm floral organ development contain at least one SEP TF. Whether DNA-binding by SEP-containing dimeric MADS complexes are sufficient for launching floral organ identity programs, however, is not clear as only defects in floral meristem determinacy were observed in tetramerization impaired SEP mutants. Here we used a combination of genome-wide binding studies, high resolution structural studies of the SEP3-AGAMOUS tetramerisation domain, structure-based mutagenesis and complementation experiments in sep1 sep2 sep3 and sep1 sep2 sep3 ag-4 plants transformed with versions of SEP3 encoding tetramerization mutants. We demonstrate that while SEP3 heterodimers are able to bind DNA both in vitro and in vivo and recognize the majority of SEP3 wild type binding sites genome-wide, tetramerisation is not only required for floral meristem determinacy, but also absolutely required for floral organ identity in the second, third and fourth whorls.

Project description:The MADS transcription factors (TF) constitute an ancient family of TF found in all eukaryotes that bind DNA as obligate dimers. Plants have dramatically expanded the functional diversity of the MADS family during evolution by adding protein-protein interaction domains to the core DNA-binding domain, allowing the formation of heterotetrameric complexes. Tetramerization of plant MADS TFs is believed to play a central role in the evolution of higher plants by acting as one of the main determinants of flower formation and floral organ specification. The MADS TF, SEPALLATA3 (SEP3), functions as a central protein-protein interaction hub, driving tetramerization with other MADS TFs. Here, we use a SEP3 splice variant, SEP3?tet, which has dramatically abrogated tetramerization capacity to decouple SEP3 tetramerization and DNA-binding activities. We unexpectedly demonstrate that SEP3 heterotetramer formation is required for correct termination of the floral meristem, but plays a lesser role in floral organogenesis. The heterotetramer formed by SEP3 and the MADS protein, AGAMOUS, is necessary to activate two target genes, KNUCKLES and CRABSCLAW, which are required for meristem determinacy. These studies reveal unique and highly specific roles of tetramerization in flower development and suggest tetramerization may be required to activate only a subset of target genes in closed chromatin regions.

Project description:In order to identify the molecular mechanism of MCPH1 antagonizing necroptosis， we performed affinity purification of MCPH1 protein complexes in TSZ-treated L929 cells, L929 cells were stably expressing Flag-tagged MCPH1 and treated with T+S+Z (T: 50 ng/ml TNFα, S: 100 nM SmacM, Z: 20 μM zVAD) for 1 hour. The resulting cells were lysed in NETN buffer (20 mM Tris-HCl [pH 8.0], 100 mM NaCl, 1 mM EDTA, and 0.5% NP-40, containing protease and phosphatase inhibitors cocktail) on ice for 30 min. Cell debris were eliminated by centrifugation and the supernatant was incubated with anti-Flag beads. After the 4 hours incubation, beads were washed with 1 mL NTEN buffer for three times, beads were boiled in 30 μL 2×SDS loading buffer and the immunocomplexes were eluted. Samples were resolved on 10% SDS-PAGE and analyzed by mass spectrometry. To elucidate the molecular mechanism behind MCPH1 nuclear translocation upon DNA damage, we performed affinity purification of MCPH1 protein complexes in response to camptothecin (CPT) treatment. HEK293T cells stably expressing SFB-tagged MCPH1 were lysed in NETN buffer (20 mM Tris-HCl [pH 8.0], 100 mM NaCl, 1 mM EDTA, and 0.5% NP-40, containing protease and phosphatase inhibitors cocktail) on ice for 30 min. Cell debris were eliminated by centrifugation and the supernatant were obtained and incubated with 50 μL S-protein beads at 4 ℃. After the 4 hours incubation, beads were washed with 1 mL NTEN buffer for three times, beads were boiled in 30 μL 2×SDS loading buffer and the immunocomplexes were eluted. Samples were resolved on 10% SDS-PAGE and analyzed by mass spectrometry.