Nf2/FGFR1/AKT axis directs cranial neural crest–derived skull morphogenesis via collagen synthesis and trafficking
Yuping Huang, Junguang Liao, Panpan Shen, Yiliang He, Fuju Sun, Qi Zhang, Changlin Zheng, Xingen Zhang, Haibo Li, Guiqian Chen
Yuping Huang, Junguang Liao, Panpan Shen, Yiliang He, Fuju Sun, Qi Zhang, Changlin Zheng, Xingen Zhang, Haibo Li, Guiqian Chen
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Research Article Bone biology Cell biology

Nf2/FGFR1/AKT axis directs cranial neural crest–derived skull morphogenesis via collagen synthesis and trafficking

Abstract

Cranial neural crest cells (CNCs) play a critical role in craniofacial bone morphogenesis, engaging in intricate interactions with various molecular signals to ensure proper development, yet the molecular scaffolds coordinating these processes remain incompletely defined. Here, we identify neurofibromin 2 (Nf2) as a critical regulator to direct CNC-derived skull morphogenesis. Genetic ablation of Nf2 in murine CNCs causes severe craniofacial anomalies, featuring declined proliferation and increased apoptosis in osteoprogenitors, impaired type I collagen biosynthesis and trafficking, and aberrant osteogenic mineralization. Mechanistically, we uncover that Nf2 serves as a molecular linker that individually interacts with FGF receptor 1 (FGFR1) and Akt through spatially segregated phosphor-sites, and structural modeling and mutagenesis identified Ser10 and Thr230 as essential residues, with Thr230 mutation selectively ablating Akt binding while preserving FGFR1 association. Strikingly, Akt inhibition phenocopied Nf2 deficiency, reducing collagen production and Nf2 phosphorylation, whereas phospho-mimetic Nf2 (T230D) rescued CNC-derived osteogenic defects in Nf2-mutant animals. Our findings underscore the physiological significance of Nf2 as a phosphorylation-operated scaffold licensing the FGFR1/AKT axis to regulate collagen type I biogenesis and trafficking, ensuring normal CNC-derived osteogenesis and craniofacial bone development, thus exposing the Nf2/FGFR1/AKT signaling axis as a therapeutic target and promising advancements in treatment of craniofacial anomalies.

Authors

Yuping Huang, Junguang Liao, Panpan Shen, Yiliang He, Fuju Sun, Qi Zhang, Changlin Zheng, Xingen Zhang, Haibo Li, Guiqian Chen

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Figure 1

Neural crest–specific Nf2 deletion impairs craniofacial bone development.

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Neural crest–specific Nf2 deletion impairs craniofacial bone development...
(A) Whole-mount skeletal staining (Alcian blue and Alizarin red) reveals severe craniofacial defects in Nf2-mutant mice at E17.5 and newborn stages, with hypoplastic frontal (fb), parietal (pb), interparietal (ib), and occipital (oc) bones. Nasal bones (na), mandible (ma), and maxilla (mx) are indicated. Scale bars: 2 mm. (BD) H&E staining shows reduced frontal and parietal bone thickness in Nf2 mutants at E16.5, which is quantified in C and D. (EG) Histochemical analysis demonstrated impaired CNC-derived osteogenesis in Nf2-mutant mice. (E) Diminished ALP activity at E18.5. Scale bars: 100 μm. (F) Declined mineralization (von Kossa) at E18.5. (G) Decreased calcified matrix (alizarin red S staining) at E18.5. (HJ) Primary CNC cultures recapitulate in vivo defects. (H) ALP staining (D7) shows impaired differentiation. Scale bars: 400 μm. (I) Alizarin red S staining (D14) confirmed deficient mineralization. Scale bars: 400 μm. (J) Quantification of calcified nodules. Data were expressed as means ± SD, and each dot represents an individual biological replicate. P values were calculated by unpaired Student’s t test with 2-tailed analysis without adjustments. *P < 0.05, **P < 0.01.