1. The KMT2D Kabuki syndrome histone methylase controls neural crest cell differentiation and facial morphology
- Author
-
Kai Ge, Cassidy L. Mangini, Terry Magnuson, Karl B. Shpargel, and Guojia Xie
- Subjects
Biology ,03 medical and health sciences ,Chondrocytes ,0302 clinical medicine ,Cell Movement ,Osteogenesis ,Histone methylation ,Morphogenesis ,medicine ,Animals ,Abnormalities, Multiple ,Cell Lineage ,Craniofacial ,Molecular Biology ,Endochondral ossification ,Alleles ,030304 developmental biology ,Mice, Knockout ,0303 health sciences ,Palate ,Ossification ,Skull ,Neural crest ,Cell Differentiation ,Histone-Lysine N-Methyltransferase ,medicine.disease ,Hematologic Diseases ,Hypoplasia ,Cell biology ,Mice, Inbred C57BL ,Neural crest cell differentiation ,Phenotype ,Vestibular Diseases ,Neural Crest ,Face ,Mutation ,medicine.symptom ,Kabuki syndrome ,Myeloid-Lymphoid Leukemia Protein ,030217 neurology & neurosurgery ,Research Article ,Developmental Biology - Abstract
Kabuki syndrome (KS) is a congenital craniofacial disorder resulting from mutations in the KMT2D histone methylase (KS1) or the UTX histone demethylase (KS2). With small cohorts of KS2 patients, it is not clear if differences exist in clinical manifestations relative to KS1. We mutated KMT2D in neural crest cells (NCCs) to study cellular and molecular functions in craniofacial development with respect to UTX. Similar to UTX, KMT2D NCC knockout mice demonstrate hypoplasia with reductions in frontonasal bone lengths. We have traced the onset of KMT2D and UTX mutant NCC frontal dysfunction to a stage of altered osteochondral progenitor differentiation. KMT2D NCC loss of function does exhibit unique phenotypes distinct from UTX mutation including fully penetrant cleft palate, mandible hypoplasia, and deficits in cranial base ossification. KMT2D mutant NCCs lead to defective secondary palatal shelf elevation with reduced expression of extracellular matrix components. KMT2D mutant chondrocytes in the cranial base fail to properly differentiate leading to defective endochondral ossification. We conclude that KMT2D is required for appropriate cranial NCC differentiation and KMT2D specific phenotypes may underlie differences between Kabuki syndrome subtypes.
- Published
- 2020
- Full Text
- View/download PDF