Van Maldergem Syndrome (VMS) is a rare autosomal recessive disorder caused by pathogenic variants in the atypical cadherin genes DCHS1 or FAT4 and is marked by craniofacial, skeletal, and neurodevelopmental abnormalities. Although DCHS1–FAT4 binding is mediated by their respective extracellular domains, the in vivo function of the DCHS1 intracellular domain (ICD) is poorly defined. To test its function, we generated mice in which the DCHS1 ICD was deleted and replaced with a V5 epitope tag (Dchs1ΔICD-V5). Homozygous Dchs1ΔICD-V5/ΔICD-V5 mice are viable but exhibit VMS-like craniofacial flattening with enlarged fontanelles and reduced palatine/maxillary structures, along with airway cartilage abnormalities including reduced mineralization and decreased tracheal circularity. In periventricular regions, wild-type DCHS1 expression shows polarized localization, whereas mice with the ICD deletion exhibit altered cell polarization within the subventricular zone, concomitant with changes in neural cellular distribution. Neonatal brains display reduced pYAP1: YAP1 ratios and increased Ki67+ proliferation with greater Ki67–neuronal co-localization within the periventricular zone. Together, these data identify the DCHS1 ICD as a critical effector for DCHS1 signaling and a regulator of polarity-dependent growth, with associated changes in Hippo pathway activity during craniofacial and neural morphogenesis. Additionally, our data establish Dchs1ΔICD-V5/ΔICD-V5 mice as a model that recapitulates core features of VMS, thereby allowing new mechanistic discoveries into its pathogenesis.
Byerly et al. (Thu,) studied this question.