Project description:The formation of maxillary prominence in vertebrates involves precisely coordinated migration and differentiation of neural crest cells. However, the regulatory factors and networks underpinning such an intricate process has not been fully elucidated. Here we combined bulk and single-cell RNA-Seq to comprehensively characterize the transcriptome dynamics during mouse maxillary development from embryonic day (E) 10.5 to 12.5, a critical period when a multitude of facial tissues start to emerge. We identified multiple cell populations that represent different developmental transition states and inferred the developmental trajectory of maxillary mesenchyme, revealing that a developmental bifurcation toward either an osteochondrogenic fate or a non-osteochondrogenic fate occurs at E11.5. We further deduced the core transcriptional regulators and gene regulatory networks associated with the maxillary cell fate transitions. Moreover, we revealed transcriptional regulators that are linked to dynamic changes in chromatin accessibility during maxillary development. Collectively, our study for the first time characterized the maxillary developmental process at single cell resolution, providing rich resources and important insights for achieving a systems level understanding of craniofacial morphogenesis and abnormality.

Project description:During embryonic development of vertebrates, neural crest- derived mesenchymal cells within the maxillary prominences undergo precisely coordinated proliferation and differentiation to give rise to a series of craniofacial structures, such as tooth and secondary palate. However, the transcriptional regulatory networks underpinning such an intricate process have not been fully elucidated. Here we combined bulk and single-cell RNA-Seq to comprehensively characterize the transcriptome dynamics during mouse maxillary development from embryonic day (E) 10.5 to 14.5. We identified mesenchymal cell populations that represent different developmental states and inferred their developmental trajectory, demonstrating that a cell fate divergence toward the palatal versus dental mesenchyme lineage occurs at E11.5. We further identified the core transcriptional regulators associated with maxillary cell fate transitions and deduced the gene regulatory networks directed by these factors. We further demonstrated that Foxp1 regulates genes involved in skeletal and cartilage development and is required for efficient osteogenesis. Collectively, our study provides rich resources and important insights for achieving a systems level understanding of craniofacial morphogenesis and abnormality.

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

Project description:Craniofacial morphogenesis is an intricate process that requires precise regulation of cell proliferation, migration, and differentiation. Perturbations of this process cause a series of craniofacial deformities. Dlx2 is a critical transcription factor that regulates the development of the first branchial arch. However, the transcriptional regulatory functions of Dlx2 during craniofacial development have been poorly understood due to the lack of animal models in that the levels of Dlx2 can be precisely modulated. In this study, we constructed a Rosa26 site-directed Dlx2 gene knock-in mouse model Rosa26CAG-LSL-Dlx2-3xFlag for conditionally overexpressing Dlx2. By breeding with Wnt1cre mice, we obtained Wnt1cre; Rosa26Dlx2/- mice in which Dlx2 is overexpressed in neural crest lineage at about three times the endogenous level. The Wnt1cre; Rosa26Dlx2/- mice exhibited consistent phenotypes that include cleft palate across generations and individual animals. Using this model, we demonstrated that Dlx2 caused cleft palate by affecting maxillary growth in the early-stage development of maxillary prominences. By performing bulk RNA-seq, we demonstrated that the overexpression of Dlx2 induced significant changes of many genes related to critical developmental pathways. In summary, our novel mouse model provides a reliable and consistent system for investigating the functions of Dlx2 during development and for dissecting the gene regulatory networks underlying craniofacial development.

Project description:We used laser capture microdissection to isolate maxillary arch mesenchyme from E10.5 embryos. This tissue was collected from both control (3x) and Lhx6-/-;Lhx8-/- mutant (3x) samples. Transcriptional profiling was performed using Affymetrix GeneChip Mouse Genome 430 2.0 arrays. The mutant mice are of mixed genetic background of C57BL/6J, 129 and CD-1 strains. The head of E10.5 embryos was collected and embedded in Optimal Cutting Temperature resin (Tissue-Tek) by flash freezing on dry ice. The frozen sections were collected on polyethylene naphthalate membrane slides (Leica). Leica LMD6000 Laser Micro-Dissection System was used to cut out the normal expression domain of Lhx6 and Lhx8 in the maxillary arch mesenchyme. The tissue was collected from the entire antero-posterior extent of the maxillary arches. Total RNA was extracted using RNeasy Micro Kit (Qiagen). Subsequent steps of transcriptional profiling were performed by the New York University Genome Technology Center, beginning with the amplification of RNA by Ovation Nano Amplification system (NuGen). RNA samples from three wild-type and three Lhx6−/−;Lhx8−/− mutant embryos, all somite count- and sex-matched (females), were analyzed with Affymetrix GeneChip Mouse Genome 430 2.0 arrays. A list of Lhx-regulated genes were generated from the microarray result based on the following criteria: fold change in the average expression between wild types and Lhx6−/−;Lhx8−/− mutants is >1.5, the difference is statistically significant (P < 0.05) and the average intensity of the probe signal is >100 for wild-type and/or mutant samples. The resulting list of 212 genes was used for a gene ontology analysis with DAVID (27,28).

Project description:Stem cell fate is governed by the integration of intrinsic and extrinsic positive and negative signals upon inherent transcriptional networks. To identify novel embryonic stem cell (ESC) regulators and assemble transcriptional networks controlling ESC fate, we performed temporal expression microarray analyses of ESCs following the initiation of commitment and integrated these data with known genome-wide transcription factor binding. Effects of forced under- or over-expression of predicted novel regulators, defined as differentially expressed genes with potential binding sites for known regulators of pluripotency, demonstrated greater than 90% correspondence with predicted function, as assessed by functional and high content assays of self-renewal. We next assembled 43 theoretical transcriptional networks in ESCs, 82% (23 out of 28 tested) of which were supported by analysis of genome-wide expression in Oct4 knockdown cells. By using this integrative approach we have, for the first time, formulated novel networks describing gene repression of key developmental regulators in undifferentiated ESCs and successfully predicted the outcomes of genetic manipulation of these networks. Experiment Overall Design: 1, 3, and 5 days LIF differentiated ESCs, and 1 and 2 days RA differentiated ESCs

Project description:The project is based on in-bone digestion of proteins by trypsin directly in human maxillary and mandibular healthy and pathological bone samples without the prior reduction and alkylation of the disulfide bonds. The released peptides were then separated and identified by LC-MS/MS method.

Project description:We used laser capture microdissection to isolate maxillary arch mesenchyme from E10.5 embryos. This tissue was collected from both control (3x) and Lhx6-/-;Lhx8-/- mutant (3x) samples. Transcriptional profiling was performed using Affymetrix GeneChip Mouse Genome 430 2.0 arrays.

Project description:Transcription factor Dlx2 plays an important role in craniomaxillofacial development. Overexpression or null mutation can lead to craniomaxillofacial malformation in mice. Although some in vivo or in vitro experiments have explored part information about the mechanism of Dlx2 regulation, there is still a lack of complete description. Using a mouse model that can stably overexpress Dlx2 in neural crest cells, the authors conducted bulk RNA-Seq, scRNA-Seq and CUT&Tag on the early maxillary processes of mice, and comprehensively described the effects of Dlx2 overexpression on the early development of maxillary processes. Bulk RNA-Seq results showed that Dlx2 had greater interference on nerve development at E10.5, and gradually affected bone development at E12.5. ScRNA-Seq proved that overexpression of Dlx2 did not change the differentiation type of mesenchymal cells during this development process, but it would restrict the proliferation of cells and make mesenchymal cells differentiate prematurely, thus limiting the development of maxillary. CUT&Tag suggested that this regulatory process is closely related to Notch signaling pathway, and MNT and RUNX2, as direct downstream regulatory target genes of Dlx2, also play a very critical role.

Project description:Transcription factor Dlx2 plays an important role in craniomaxillofacial development. Overexpression or null mutation can lead to craniomaxillofacial malformation in mice. Although some in vivo or in vitro experiments have explored part information about the mechanism of Dlx2 regulation, there is still a lack of complete description. Using a mouse model that can stably overexpress Dlx2 in neural crest cells, the authors conducted bulk RNA-Seq, scRNA-Seq and CUT&Tag on the early maxillary processes of mice, and comprehensively described the effects of Dlx2 overexpression on the early development of maxillary processes. Bulk RNA-Seq results showed that Dlx2 had greater interference on nerve development at E10.5, and gradually affected bone development at E12.5. ScRNA-Seq proved that overexpression of Dlx2 did not change the differentiation type of mesenchymal cells during this development process, but it would restrict the proliferation of cells and make mesenchymal cells differentiate prematurely, thus limiting the development of maxillary. CUT&Tag suggested that this regulatory process is closely related to Notch signaling pathway, and MNT and RUNX2, as direct downstream regulatory target genes of Dlx2, also play a very critical role.