Twisted gastrulation mutation suppresses skeletal defect phenotypes in Crossveinless 2 mutant mice

Bone morphogenetic protein (BMP) signaling controls various aspects of organogenesis, including skeletal development. We previously demonstrated that the pro-BMP function of Crossveinless 2 (Cv2) is required for axial and non-axial skeletal development in mice. Here, we showed that skeletal defects in the Cv2-null mutant were reversed by the additional deletion of Twisted gastrulation (Tsg). Whereas the Cv2(-/-) mutant lacks a substantial portion of the lumbar vertebral arches, Cv2(-/-);Tsg(-/-) mice have almost normal arches. Suppression of Cv2(-/-) phenotypes is also seen in the non-axial skeleton, including the ribs, humerus, skull, and laryngeal and tracheal cartilages. In contrast, the Tsg(-/-) phenotype in the head is not significantly affected by the Cv2 mutation. These findings demonstrate that Tsg mutation is epistatic to Cv2 mutation in the major skeletal phenotypes, suggesting that the pro-BMP activity of Cv2 is, at least in part, dependent on Tsg. We also present genetic evidence for the context-dependent functional relationship between Tsg and Cv2 during mouse development.     

Chondrocyte-specific microRNA-140 regulates endochondral bone development and targets Dnpep to modulate bone morphogenetic protein signaling

MicroRNAs (miRNAs) play critical roles in a variety of biological processes in diverse organisms, including mammals. In the mouse skeletal system, a global reduction of miRNAs in chondrocytes causes a lethal skeletal dysplasia. However, little is known about the physiological roles of individual miRNAs in chondrocytes. The miRNA-encoding gene, Mir140, is evolutionarily conserved among vertebrates and is abundantly and almost exclusively expressed in chondrocytes. In this paper, we show that loss of Mir140 in mice causes growth defects of endochondral bones, resulting in dwarfism and craniofacial deformities. Endochondral bone development is mildly advanced due to accelerated hypertrophic differentiation of chondrocytes in Mir140-null mice. Comparison of profiles of RNA associated with Argonaute 2 (Ago2) between wild-type and Mir140-null chondrocytes identified Dnpep as a Mir140 target. As expected, Dnpep expression was increased in Mir140-null chondrocytes. Dnpep overexpression showed a mild antagonistic effect on bone morphogenetic protein (BMP) signaling at a position downstream of Smad activation. Mir140-null chondrocytes showed lower-than-normal basal BMP signaling, which was reversed by Dnpep knockdown. These results demonstrate that Mir140 is essential for normal endochondral bone development and suggest that the reduced BMP signaling caused by Dnpep upregulation plays a causal role in the skeletal defects of Mir140-null mice.     

Loss-of-function of ACVR1 in osteoblasts increases bone mass and activates canonical Wnt signaling through suppression of Wnt inhibitors SOST and DKK1

BMPs (Bone morphogenetic proteins) such as BMP2 and BMP7 have been used about one decade as bone anabolic agents in orthopaedics. The BMP receptor ACVR1, which is a key receptor of BMP7, is expressed in bone. The pathological role of ACVR1 in humans has been reported: a point mutation in ACVR1 can cause fibrodysplasia ossificans progressiva (FOP) in which ectopic ossification occurs in skeletal muscles and deep connective tissues. The physiological function of ACVR1 in bone, however, is totally unknown. The purpose of this study is to investigate the endogenous role of ACVR1 in osteoblasts, one of the most dominant cell-types in bone. We generated Acvr1-null mice in an osteoblast-specific manner using an inducible Cre-loxP system. Surprisingly, we found that bone mass was increased in the Acvr1-null mice. Interestingly, canonical Wnt signaling was increased and expression levels of Wnt inhibitors Sost and Dkk1 were both suppressed in the null bones during the developmental stages. In addition, we confirmed that expression levels of both Sost and Dkk1 were upregulated by BMP7 dose-dependently in vitro. These results suggest that the Acvr1-deficiency can increase bone mass by activating Wnt signaling in which both Sost and Dkk1 expression levels are diminished. This study leads to a new concept of the BMP7-ACVR1-SOST/DKK1 axis in osteoblasts, in which BMP7 signaling through ACVR1 can reduce Wnt signaling via SOST/DKK1 and then inhibits osteogenesis. Although this concept is beyond the current known function of BMP7, it can explain the varied outcomes of BMP7 treatment. We believe BMP signaling can exhibit multifaceted effects by context and cell type.     

Deletion of the Sequence Encoding the Tail Domain of the Bone Morphogenetic Protein type 2 Receptor Reveals a Bone Morphogenetic Protein 7-Specific Gain of Function

The bone morphogenetic protein (BMP) type II receptor (BMPR2) has a long cytoplasmic tail domain whose function is incompletely elucidated. Mutations in the tail domain of BMPR2 are found in familial cases of pulmonary arterial hypertension. To investigate the role of the tail domain of BMPR2 in BMP signaling, we generated a mouse carrying a Bmpr2 allele encoding a non-sense mediated decay-resistant mutant receptor lacking the tail domain of Bmpr2. We found that homozygous mutant mice died during gastrulation, whereas heterozygous mice grew normally without developing pulmonary arterial hypertension. Using pulmonary artery smooth muscle cells (PaSMC) from heterozygous mice, we determined that the mutant receptor was expressed and retained its ability to transduce BMP signaling. Heterozygous PaSMCs exhibited a BMP7‑specific gain of function, which was transduced via the mutant receptor. Using siRNA knockdown and cells from conditional knockout mice to selectively deplete BMP receptors, we observed that the tail domain of Bmpr2 inhibits Alk2‑mediated BMP7 signaling. These findings suggest that the tail domain of Bmpr2 is essential for normal embryogenesis and inhibits Alk2‑mediated BMP7 signaling in PaSMCs.     

BMP signaling is required for septation of the outflow tract of the mammalian heart

Bone morphogenetic proteins (BMPs) constitute a family of approximately 20 growth factors involved in a tremendous variety of embryonic inductive processes. BMPs elicit dose-dependent effects on patterning during gastrulation and gradients of BMP activity are thought to be established through regulation of the relative concentrations of BMP receptors, ligands and antagonists. We tested whether later developmental events also are sensitive to reduced levels of BMP signaling. We engineered a knockout mouse that expresses a BMP type II receptor that lacks half of the ligand-binding domain. This altered receptor is expressed at levels comparable with the wild-type allele, but has reduced signaling capability. Unlike Bmpr2-null mice, mice homozygous for this hypomorphic receptor undergo normal gastrulation, providing genetic evidence of the dose-dependent effects of BMPs during mammalian development. Mutants, however, die at midgestation with cardiovascular and skeletal defects, demonstrating that the development of these tissues requires wild-type levels of BMP signaling. The most striking defects occur in the outflow tract of the heart, with absence of septation of the conotruncus below the valve level and interrupted aortic arch, a phenotype known in humans as persistent truncus arteriosus (type A4). In addition, semilunar valves do not form in mutants, while the atrioventricular valves appear unaffected. Abnormal septation of the heart and valve anomalies are the most frequent forms of congenital cardiac defects in humans; however, most mouse models display broad defects throughout cardiac tissues. The more restricted spectrum of cardiac anomalies in Bmpr2(deltaE2) mutants makes this strain a key murine model to understand the embryonic defects of persistent truncus arteriosus and impaired semilunar valve formation in humans.