Project description:This study aimed to further understand context-specific direct Wnt target gene expression through the use of beta-catenin and FoxH1 ChIP Sequencing data at various developmental stages representing both maternal and zygotic Wnt signalling. Results were further supported through the use of RNA sequencing data from beta-catenin, FoxH1 and nodal gene knock down assays.

Project description:Brachyury (Xbra/Xbra3) knock-down embryos of the frog Xenopus tropicalis were profiled to quantify neuro-mesodermal cell fate switches at a transcriptional level. Transcriptional profiling of Xbra/Xbra3 double morphants at early tadpole stage (RNA-Seq) in biological triplicates.

Project description:During embryonic development, maintenance of cell identity and lineage commitment requires the Polycomb-group PRC2 complex, which catalyzes histone H3 K27 trimethylation (H3K27me3). However, the developmental origins of this regulation are unknown. Here, we report on H3K27me3 deposition dynamics in Xenopus embryos, on sequence elements that initiate deposition during pluripotency, and the sequence characteristics that segregate Polycomb-regulated domains from the rest of the genome. Strikingly, although PRC2 binds widely to active enhancers, H3K27me3 is only deposited at a small subset of these sites. Using a Support Vector Machine algorithm these sequences can be predicted accurately on basis of DNA sequence alone, with a sequence signature conserved between humans, frog and fish. The results suggest a genetic-default model in which genomic sequence constrains Polycomb regulation. ChIP-seq profiles of three histone modifications (H3K4me3, H3K27me3 and H3K4me1) and RNA Polymerase II, EZH2 and Jarid2 of Xenopus tropicalis embryos during development

Project description:V1 interneurons are a class of inhibitory neurons that play an essential role in vertebrate locomotion; however, the factors contributing to their specification are poorly understood. Morphological and molecular evidence suggest that the zinc finger transcription factor Prdm12 may play a role in promoting V1 interneurons while repressing V2 and V0 fates. Here, we performed RNAseq on Xenopus laevis ectoderm converted to posteriorized neural tissue (with noggin and retinoic acid) in the presence or absence of a series of Prdm12 constructs (wild-type Prdm12, Prdm12-VP16, and Prdm12-engrailed-repressor). We also performed ChIPseq on a Prdm12-FLAG in wild-type or posteriorized neuralized (with noggin and retinoic acid) X. laevis ectoderm. Taken together, these data demonstrate Prdm12's genomic targets and their downstream transcription. X. laevis embryos were injected with mRNAs encoding prdm12 constructs, along with the bmp inhibitor noggin. Presumptive ectoderm (neuralized by noggin) was dissected and treated with retinoic acid. Samples were then processed into RNAseq libraries or prdm12-FLAG was immunoprecipitated and its targets sequenced. Background was input prior to IP.

Project description:Here we report on genome-wide small RNA and transcriptome profiling of blastula, gastrula and neurula-stage Xenopus tropicalis embryos using deep sequencing. By combining bioinformatic analysis of the small RNA-seq dataset with experimental validation, we identify novel microRNAs and Piwi-interacting RNAs. We show that microRNA expression is highly dynamic and spatially localized in early embryos in contrast to Piwi-interacting RNAs, and we validate a novel microRNA prediction pipeline. We go on to identify a new class of small intronic non-coding RNAs, that we name sincRNAs. On a genome-wide scale we find that genes containing sincRNA clusters are transcriptionally repressed. Our data suggest a novel mechanism of sincRNA-mediated gene silencing in vertebrates. Examination of small RNAs and mRNA at 3 stages of Xenopus embryonic development.

Project description:Xenopus laevis embryos were injected with antisense oligonucleotides against TBP, TLF or TBP2. Embryos were allowed to develop up to stage 7 (non-injected control embryos) or stage 10.5 (early gastrula, control and antisense injected embryos) and subsequently collected for RNA and protein isolation. The transcriptome profile of antisense injected and control embryos was compared.

Project description:Xenopus laevis embryos were injected with alpha-amanitin to inhibit RNA polymerase II activity. Embryos were allowed to develop up to stage 10.5 (early gastrula, control and alpha-amanitin injected embryos) and subsequently collected for RNA isolation. The transcriptome profiles of alpha-amanitin injected and control embryos were compared.

Project description:We characterized the cilia proteome isolated from the multi-ciliated cells of Xenopus laevis embryo epidermis.

Project description:We aimed to identify genes that are inhibited by Kctd15 overexpression during neural crest (NC) induction. Injection of RNAs encoding Wnt3a and chordin into the embryo followed by animal cap explant culture leads to the induction of NC marker genes as well as additional genes expressed in the neural plate border. Our previous study indicated that co-injection of kctd15 inhibits the induction of these markers. We injected four sets of RNAs, lacZ as control (L), wnt3a+chd (WC), wnt3a+chd+kctd15 (WCK), and kctd15 (K). After evaluation of marker gene expression with RT-PCR, we prepared probes with same RNA extract for Affymetrix DNA microarray. The hybridization, washing and scanning were perfomed following the manual from Affymetrix. Partek Genomics Suite was employed for data analysis. Xenopus embryos were injected with mRNAs at two-cell stage. When developing to stage 9, the animal caps were dissected for RNA extraction and hybridization on Affymetrix microarrays. According to the mRNAs injected, the animal caps (AC) were divided into four groups, including (1) AC injected with lacZ; (2) AC injected with kctd15; (3) AC injected with chordin and wnt3a; (4) AC injected with chordin, wnt3a and kctd15. The injected animal caps were cultured till stage 15 and then collected for RT-PCR and microarray assay. Each group had three repeats.

Project description:Eye development is a multistep process that requires specific inductive signals and precise morphogenetic movements, starting early during development in the eye-field, a well-definite region of the anterior neural plate. It has been demonstrated that a gene network of eye field transcription factors (EFTFs) contributes to specify the neural and retinal fate of the eye field. Among these EFTFs, Xrx1 is involved in proliferation and neurogenesis in the eye field and is necessary for the correct development of the retina. By means of Affymetrix microarrays, a high throughput screening was performed, looking for genes that can mediate the function of Xrx1, by comparison of the expression profiles of whole embryos in which the Xrx1 function was either overexpressed or abolished by use of morpholino antisense oligonucleotides. Xenopus laevis embryos were harvested soon after fertilization. 50ng of capped Xrx1 mRNA or 0.5pmol of MoXrx1 antisense oligonucleotides were coinjected with 400ng of GFP synthetic mRNA as a tracer, in both dorsal blastomeres of 4-cells stage embryos. Embryos were let to develop until stage 13, in which the eye field induction steps are active, and selected for correct injection site by fluorescence topographic assessment. RNA was extracted from each single embryo and control PCRs were performed to assess the correct molecular signature of Xrx1 loss- and gain- of function.