Abstract
BackgroundMice with a loss of function mutation in Wdpcp were described previously to display severe birth defects in the developing heart, neural tube, and limb buds. Further characterization of the skeletal phenotype of Wdpcp null mice was limited by perinatal lethality.ResultsWe utilized Prx1-Cre mice to generate limb bud mesenchyme specific deletion of Wdpcp. These mice recapitulated the appendicular skeletal phenotype of the Wdpcp null mice including polydactyl and limb bud signaling defects. Examination of late stages of limb development demonstrated decreased size of cartilage anlagen, delayed calcification, and abnormal growth plates. Utilizing in vitro assays, we demonstrated that loss of Wdpcp in skeletal progenitors lead to loss of hedgehog signaling responsiveness and associated proliferative response. In vitro chondrogenesis assays showed this loss of hedgehog and proliferative response was associated with decreased expression of early chondrogenic marker N-Cadherin. E14.5 forelimbs demonstrated delayed ossification and expression of osteoblast markers Runx2 and Sp7. P0 growth plates demonstrated loss of hedgehog signaling markers and expansion of the hypertrophic zones of the growth plate. In vitro osteogenesis assays demonstrated decreased osteogenic differentiation of Wdpcp null mesenchymal progenitors in response to hedgehog stimulation.ConclusionsThese findings demonstrate how Wdpcp and associated regulation of the hedgehog signaling pathway plays an important role at multiple stages of skeletal development. Wdpcp is necessary for positive regulation of hedgehog signaling and associated proliferation is key to the initiation of chondrogenesis. At later stages, Wdpcp facilitates the robust hedgehog response necessary for chondrocyte hypertrophy and osteogenic differentiation.
Highlights
Mice with a loss of function mutation in Wdpcp were described previously to display severe birth defects in the developing heart, neural tube, and limb buds
While examination of later stages in skeletal development of these mutants has been limited by lethality, analysis of the limb buds demonstrates polydactyly and altered hedgehog signaling
We examined the responsiveness of limb mesenchymal progenitor cells to Smo stimulation with Smo agonist (SAG) treatment, and saw a significantly diminished responsiveness in the Wdpcp-cKO cells in expression of the two hedgehog pathway responsive genes Gli1 and Ptch1 [32] (Fig. 3E, F) that correlated with decreased cilia formation
Summary
Mice with a loss of function mutation in Wdpcp were described previously to display severe birth defects in the developing heart, neural tube, and limb buds. Further characterization of the skeletal phenotype of Wdpcp null mice was limited by perinatal lethality. The CPLANE complex has been shown to regulate intraflagellar transport proteins (IFT) necessary for formation of the primary cilium [5]. The role of CPLANE proteins in skeletal development has been less intensively studied, Wdpcp−/− [17], Fuz−/− [18], and Intu−/− [19, 20] mice have been characterized. While examination of later stages in skeletal development of these mutants has been limited by lethality, analysis of the limb buds demonstrates polydactyly and altered hedgehog signaling
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