Project description:The ectomesenchyme generates much of the craniofacial skeleton, sutures, and diverse connective tissues in the mammalian head, yet its derivation from embryonic stem cells (ESCs) and the underlying molecular drivers remain poorly defined. Here, we identified Dlx2 as a key regulator that efficiently directed murine ESCs towards Msx1+ ectomesenchyme, recapitulating the developmental trajectory. These Msx1+ progenitors expressed classical craniofacial markers and retained robust osteochondral bipotency in vitro and in vivo. Mechanistically, DLX2 utilized a lamina-associated polypeptide 2 (LAP2)-dependent nuclear chaperoning system, engaging LAP2α via a 38-amino-acid homeodomain motif to interact with nucleosomes, thereby opening chromatin and activating a craniofacial ectomesenchymal gene network. Disrupting DLX2-LAP2α interaction or silencing Dlx2 targets largely diminished ectomesenchymal differentiation. Our findings established DLX2 as a pioneer factor in ectomesenchyme specification, offering insights into craniofacial development and stem cell engineering.

Project description:The ectomesenchyme generates much of the craniofacial skeleton, sutures, and diverse connective tissues in the mammalian head, yet its derivation from embryonic stem cells (ESCs) and the underlying molecular drivers remain poorly defined. Here, we identified Dlx2 as a key regulator that efficiently directed murine ESCs towards Msx1+ ectomesenchyme, recapitulating the developmental trajectory. These Msx1+ progenitors expressed classical craniofacial markers and retained robust osteochondral bipotency in vitro and in vivo. Mechanistically, DLX2 utilized a lamina-associated polypeptide 2 (LAP2)-dependent nuclear chaperoning system, engaging LAP2α via a 38-amino-acid homeodomain motif to interact with nucleosomes, thereby opening chromatin and activating a craniofacial ectomesenchymal gene network. Disrupting DLX2-LAP2α interaction or silencing Dlx2 targets largely diminished ectomesenchymal differentiation. Our findings established DLX2 as a pioneer factor in ectomesenchyme specification, offering insights into craniofacial development and stem cell engineering.

Project description:The ectomesenchyme generates much of the craniofacial skeleton, sutures, and diverse connective tissues in the mammalian head, yet its derivation from embryonic stem cells (ESCs) and the underlying molecular drivers remain poorly defined. Here, we identified Dlx2 as a key regulator that efficiently directed murine ESCs towards Msx1+ ectomesenchyme, recapitulating the developmental trajectory. These Msx1+ progenitors expressed classical craniofacial markers and retained robust osteochondral bipotency in vitro and in vivo. To unravel the molecular machinery, we performed immunoprecipitation mass spectrometry (IP-MS) of DLX2-Flag in ectomesenchymal progenitors, revealing LAP2α as a critical interactor. Mechanistically, DLX2 utilized a lamina-associated polypeptide 2 (LAP2)-dependent nuclear chaperoning system, wherein its 38-amino-acid homeodomain motif directly bound LAP2α. This interaction facilitated nucleosome engagement, chromatin remodeling, and activation of the craniofacial ectomesenchymal gene network. Functional validation showed that disrupting the DLX2-LAP2α interface (via domain deletion or competitive peptides) or silencing Dlx2 targets abolished ectomesenchymal differentiation. Our findings establish DLX2 as a pioneer factor in ectomesenchyme specification, with the DLX2-LAP2α axis serving as a linchpin for chromatin accessibility and lineage commitment, offering insights into craniofacial development and stem cell engineering.

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:Dlx2 drives Msx1+ ectomesenchymal differentiation in embryonic stem cells CutTag Data

Project description:Dlx2 drives Msx1+ ectomesenchymal differentiation in embryonic stem cells SingleCell Data

Project description:Dlx2 drives Msx1+ ectomesenchymal differentiation in embryonic stem cells RNA-seq data

Project description:The Dlx homeobox genes have central roles in controlling patterning and differentiation of the brain and craniofacial primordia. In the brain, loss of Dlx function results in defects in the production, migration and differentiation of GABAergic neurons, that can lead to epilepsy. In the branchial arches, loss of Dlx function leads to craniofacial malformations that include trigeminal axon pathfinding defects. To determine how these genes function, we wish to identify the transcriptional circuitry that lies downstream of these transcription factors by comparing gene expression in wild type with Dlx mutant CNS and craniofacial tissues. 1) Compare gene expression in the maxillay branch of the first branchial arch (BA) of E10.5 wild type and Dlx2 -/- mutants. 2) Compare gene expression in the maxillary branch of the first BA of E10.5 wild type and Dlx1/2 -/- mutants. 3) Compare gene expression in wild type maxillary and mandibular branchial arches. 4) Compare gene expressionin mandibular branch of Dlx5/6 -/- mutants with wild type mandibular branch. The Dlx transcription factors are essential for controlling patterning of the brain and craniofacial primordia. In the brain, they control differentiation of GABAergic neurons of the basal ganglia. In the branchial arches, they control regional patterning. I hypothesize that there will be some conserved and some divergent mechanisms that the Dlx genes use in controlling brain and craniofacial development. We have already performed array analyses on Dlx function in the developing basal ganglia (with TGEN) by comparing expressed genes in wild type and Dlx1/2 mutants. Here we will compare gene expression in the brachial arches of wild type and Dlx mutant mice. 1) Generate E10.5 mouse embryos that are either wild type, Dlx2-/-, Dlx1/2 -/- or Dlx5/6 -/-. 2) Determine genotype by PCR. 3) Dissect branchial arches from the different genotypes. 4) Separate maxillary and mandibular branch of each branchial arch. 5) Prepare total RNA from the specimens. Obtain sufficient tissue to obtain 10 ug of total RNA - based on previous experience we anticipate that this will require ~ 10 branchial arches. We will pool the tissue from different embryos of the same genotype. 6) Send total RNA to TGEN for probe preparation, hybridization and array result analysis.

Project description:Dlx2 drives Msx1+ ectomesenchymal differentiation in embryonic stem cells H3K27ac-dox CutTag Data

Project description:Craniofacial development requires intricate cooperation of multiple transcription factors and signaling pathways. Six1 is a critical transcription factor regulating craniofacial development. However, the exact function of Six1 during craniofacial development remains elusive. In this study, we investigated the function of Six1 in mandible development using a Six1 knockout mouse model (Six1-/-) and a cranial neural crest-specific, Six1 conditional knockout mouse model (Six1f/f; Wnt1-Cre). The Six1-/- mice exhibited multiple craniofacial deformities, including severe microsomia, high-arched palate, and uvula deformity. Importantly, the Six1f/f; Wnt1-Cre mice recapitulate the microsomia phenotype of Six1-/- mice, thus demonstrating that the expression of Six1 in ectomesenchyme is critical for mandible development. We further showed that the knockout of Six1 led to abnormal expression of osteogenic genes within the mandible. Moreover, the knockdown of Six1 in C3H10 T1/2 cells reduced their osteogenic capacity in vitro. Using RNA-seq, we showed that both the loss of Six1 in the E18.5 mandible and the Six1 knockdown in C3H10 T1/2 led to the dysregulation of genes involved in embryonal skeletal development. In particular, we showed that Six1 binds to the promoter of Bmp4, Fat4, Fgf18, and Fgfr2, and promotes their transcription. Collectively, our results suggest that Six1 plays a critical role in the regulation of mandibular skeleton formation during mouse embryogenesis.