A phenotype-driven ENU mutagenesis screen identifies novel alleles with functional roles in early mouse craniofacial development.

Proper craniofacial development begins during gastrulation and requires the coordinated integration of each germ layer tissue (ectoderm, mesoderm, and endoderm) and its derivatives in concert with the precise regulation of cell proliferation, migration, and differentiation. Neural crest cells, which are derived from ectoderm, are a migratory progenitor cell population that generates most of the cartilage, bone, and connective tissue of the head and face. Neural crest cell development is regulated by a combination of intrinsic cell autonomous signals acquired during their formation, balanced with extrinsic signals from tissues with which the neural crest cells interact during their migration and differentiation. Although craniofacial anomalies are typically attributed to defects in neural crest cell development, the cause may be intrinsic or extrinsic. Therefore, we performed a phenotype-driven ENU mutagenesis screen in mice with the aim of identifying novel alleles in an unbiased manner, that are critically required for early craniofacial development. Here we describe 10 new mutant lines, which exhibit phenotypes affecting frontonasal and pharyngeal arch patterning, neural and vascular development as well as sensory organ morphogenesis. Interestingly, our data imply that neural crest cells and endothelial cells may employ similar developmental programs and be interdependent during early embryogenesis, which collectively is critical for normal craniofacial morphogenesis. Furthermore our novel mutants that model human conditions such as exencephaly, craniorachischisis, DiGeorge, and Velocardiofacial sydnromes could be very useful in furthering our understanding of the complexities of specific human diseases.

Cranial nerve development requires co-ordinated Shh and canonical Wnt signaling.

Cranial nerves govern sensory and motor information exchange between the brain and tissues of the head and neck. The cranial nerves are derived from two specialized populations of cells, cranial neural crest cells and ectodermal placode cells. Defects in either cell type can result in cranial nerve developmental defects. Although several signaling pathways are known to regulate cranial nerve formation our understanding of how intercellular signaling between neural crest cells and placode cells is coordinated during cranial ganglia morphogenesis is poorly understood. Sonic Hedgehog (Shh) signaling is one key pathway that regulates multiple aspects of craniofacial development, but whether it co-ordinates cranial neural crest cell and placodal cell interactions during cranial ganglia formation remains unclear. In this study we examined a new Patched1 (Ptch1) loss-of-function mouse mutant and characterized the role of Ptch1 in regulating Shh signaling during cranial ganglia development. Ptch1(Wig/ Wig) mutants exhibit elevated Shh signaling in concert with disorganization of the trigeminal and facial nerves. Importantly, we discovered that enhanced Shh signaling suppressed canonical Wnt signaling in the cranial nerve region. This critically affected the survival and migration of cranial neural crest cells and the development of placodal cells as well as the integration between neural crest and placodes. Collectively, our findings highlight a novel and critical role for Shh signaling in cranial nerve development via the cross regulation of canonical Wnt signaling.

Dishevelled stabilization by the ciliopathy protein Rpgrip1l is essential for planar cell polarity.

Cilia are at the core of planar polarity cellular events in many systems. However, the molecular mechanisms by which they influence the polarization process are unclear. Here, we identify the function of the ciliopathy protein Rpgrip1l in planar polarity. In the mouse cochlea and in the zebrafish floor plate, Rpgrip1l was required for positioning the basal body along the planar polarity axis. Rpgrip1l was also essential for stabilizing dishevelled at the cilium base in the zebrafish floor plate and in mammalian renal cells. In rescue experiments, we showed that in the zebrafish floor plate the function of Rpgrip1l in planar polarity was mediated by dishevelled stabilization. In cultured cells, Rpgrip1l participated in a complex with inversin and nephrocystin-4, two ciliopathy proteins known to target dishevelled to the proteasome, and, in this complex, Rpgrip1l prevented dishevelled degradation. We thus uncover a ciliopathy protein complex that finely tunes dishevelled levels, thereby modulating planar cell polarity processes.

Pathologic calcification of adult vascular smooth muscle cells differs on their crest or mesodermal embryonic origin.

Vascular calcifications can occur in the elderly and in patients suffering from various diseases. Interestingly, depending on the pathology, different regions of the arterial system can be affected. Embryonic observations have clearly indicated that vascular smooth muscle cell (VSMC) origin is notably heterogeneous. For instance, in the aorta, VSMCs colonizing the aortic arch region derive from cardiac neural crest cells, whereas those populating the descending aorta derive from the mesoderm. We examined here whether the embryonic origin of aortic VSMCs would correlate with their ability to mineralize. Under hyperphosphatemic conditions that induce vascular calcifications, we performed ex vivo aortic explant cultures as well as in vitro VSMC cultures from wild-type mice. Our data showed that VSMC embryonic origin affects their ability to mineralize. Indeed, the aortic arch media made up of VSMCs of neural crest origin calcifies significantly earlier than the descending aorta composed of VSMCs, which are mesoderm-derived. Similar results were obtained with cultured VSMCs harvested from both aortic regions. We also demonstrated that in a mouse model deficient in matrix Gla protein, a potent calcification inhibitor, developing extensive and spontaneous medial calcifications of the aorta, lesions initiate in the aortic arch. Subsequently, calcifications progress outside the aortic arch region and ultimately spread all over the entire arterial tree, including the descending aorta. Altogether, our results support an unsuspected correlation between VSMCs of embryonic origin and the timing of appearance of calcifications.