Project description:The patterning of the facial midline involves early specification of neural crest cells to form skeletal tissues that support the upper jaw . In order to understand the molecular mechanisms involved we have taken advantage of a beak duplication model developed in the chicken embryo. Here we can induce the transformation of the side of the beak into a second midline that is easily identifiable by the formation of a supernumerary egg tooth. The phenotype is induced by implanting two microscopic beads, one soaked in retinoic acid and the other soaked in Noggin into the side of the head of the chicken embryo. Here we use microarrays to profile expression of maxillary mesenchyme 16h after placing the beads. A subset of genes were validated using in situ hybridization and QPCR. The aims of the study are to test the function of these genes using retroviral transgenesis, knockdown with morpholinos or expression of secreted proteins and their application to the embryo.

Project description:Growth and patterning of the face relies on several small buds of tissue, the facial prominences, which surround the primitive mouth. Beginning around E10 of mouse development the prominences undergo rapid growth and morphogenesis. By E11.5 the medial nasal prominences are in close apposition in the midline, as are the maxillary and medial nasal prominences on either side of the developing face. Subsequently, by E12.5 the nasal and maxillary prominences fuse to form a continuous shelf at the front of the face - the primary palate. Individual prominences are associated with specific developmental processes, and this is reflected by patterns of differential gene expression that give the prominences their unique identities. Thus, only the mandibular and maxillary prominences give rise to dentition while the frontonasal prominence has a unique role in olfaction, and the mandibular prominence in taste. We used microarrays to detail the differential gene expression program in each of the mandibular, maxillary, and frontonasal prominences during the key developmental timepoints of E10.0 through E12.5. Keywords: time course

Project description:Growth and patterning of the face relies on several small buds of tissue, the facial prominences, which surround the primitive mouth. Beginning around E10 of mouse development the prominences undergo rapid growth and morphogenesis. By E11.5 the medial nasal prominences are in close apposition in the midline, as are the maxillary and medial nasal prominences on either side of the developing face. Subsequently, by E12.5 the nasal and maxillary prominences fuse to form a continuous shelf at the front of the face - the primary palate. Individual prominences are associated with specific developmental processes, and this is reflected by patterns of differential gene expression that give the prominences their unique identities. Thus, only the mandibular and maxillary prominences give rise to dentition while the frontonasal prominence has a unique role in olfaction, and the mandibular prominence in taste. We used microarrays to detail the differential gene expression program in each of the mandibular, maxillary, and frontonasal prominences during the key developmental timepoints of E10.0 through E12.5. Experiment Overall Design: Analysis of gene expression during growth and fusion of the facial prominences in the C57BL/6J mouse strain between embryonic (E) day 10.0 and 12.5. At the earliest timepoint, E10, only the mandibular prominence is a distinct entity that can be readily identified and dissected. The frontonasal prominence and the maxillary prominence are very small and not discrete from other components of the head such as the forebrain until E10.5. Analysis of these tissues at earlier timepoints would require laser capture and preamplification steps - techniques that were not used for the later timepoints. Thus samples were isolated from the mandibular prominence at E10.0 and from the mandibular, maxillary and frontonasal prominences of mouse embryos from E10.5 to E12.5, at 0.5 day intervals. In order to obtain sufficient sample for hybridization, each sample represents a pool of between 3 and 48 embryos depending on the timepoint. Specifically, the number of embryos were 40-48 for E10.0 (mandibular prominence only), 24-8 for E10.5, 8-9 for E11.0 and E11.5 and 3-4 for E12.0 and E12.5. Seven replicate samples were taken for each of the later five timepoints in each of the three prominences, with an additional seven samples for the mandibular E10.0 timepoint, for a total of 112 samples.

Project description:Transcriptional profiling comparing the genes upregulated or downregulated by active hGR-Xebf3 by treating hormone DEX to those by non-active hGR-Xebf3 in Xenopus animal caps. Three experimental conditions, Noggin and hGR-Xebf3 without DEX treatment (1), Noggin and hGR-Xebf3 with DEX treatment (2), and Noggin and hGR with DEX treatment (3). Comparison, 1 vs.2 and 1 vs. 3. Biological replicates, 4 times

Project description:Neo/null loss of Tfap2a in E10.5 mouse facial prominences triplicate run comparing tissue dissected from the nasal, maxillary and mandibular comparing AP-2 mutant and control embryos

Project description:We report the RNA profiles of both control and talpid2 frontonasal, maxillary, and mandibular prominences of the chick face at Hamburger and Hamilton (HH) stage 25. For more details please see: "The cellular and molecular etiology of the craniofacial defects in the avian ciliopathic mutant, talpid2." Facial prominences (frontonasal, maxillary, and mandibular) from 8 control and 8 talpid2 HH 25 embryos were harvested, pooled, and RNA-seq was preformed on samples.

Project description:To confirm that the SMAD1/5- and SMAD4-associated genes are direct transcriptional regulators in mESCs in response to BMP, we treated undifferentiated R1 ES cells with BMP4 or with the BMP4 antagonist noggin, which can inhibit BMP signaling effectively for 4 h. Undifferentiated R1 ES cells were treated for 4 h with BMP4 or with the BMP4 antagonist noggin, which can inhibit BMP signaling effectively. Untreated R1 ES cells served as the control.

Project description:We present a gene expression atlas of early mouse craniofacial development. Laser capture microdissection (LCM) was used to isolate cells from the principal critical micro-regions, whose development, differentiation and signaling interactions are responsible for the construction of the mammalian face We examined the facial mesenchyme and adjacent neuroepithelium at E8.5, at E9.5 we obtain cells from the facial mesenchyme, olfactory placode/epidermal ectoderm, underlying neuroepithileium, and emerging mandibular and maxillary arches. AT E10.5 we sampled the medial and lateral prominences, olfactory pit, multiple regions of the underlying neuroepithelium the mandibular and maxillary arches, and Rathke's pouch. Mouse emrbyos were harvested at developmental stage E8.5 , E9.5, and E10.5 and cells were captured from microregions responsible for the construction of the mammalian face. RNA was extracted, labelled, and quantified using the Mouse ST-l microarray.

Project description:The face is one of the three regions most frequently affected by congenital defects in humans. In order to understand the molecular mechanisms involved it is necessary to have a more complete picture of gene expression in the embryo. Here we use microarrays to profile expression in chicken facial prominences, post neural crest migration and prior to differentiation of mesenchymal cells. Chip-wide analysis revealed that maxillary and mandibular prominences had similar expression profiles while the frontonasal mass chips were distinct. Of the 3094 genes that were differentially expressed in one or more regions of the face, a group of 56 genes was subsequently validated with quantitative PCR and a subset examined with in situ hybridization. Microarrays trends were consistent with the QPCR data for the majority of genes (81%). On the basis of QPCR and microarray data, groups of genes that characterize each of the facial prominences can be determined. We used microarrays to detail the global programme of gene expression underlying facial morphogensis Experiment Overall Design: Chicken embryos were selected at a stage after neural crest cells have ceased migration, when facial prominences have formed and prior to ctyodifferentiation of cartilage, bone, muscle. Microdissection was used to isolate facial prominences. Embryos were dissected on ice in Hanks Buffered Salt Solution and batches of 26-32 pieces were snap frozen in liquid Nitrogen. These pooled facial prominences comprised one biological replicate. A total of three biological replicates were generated for the frontonasal mass, maxillary and mandibular prominences.

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.