Constitutively active ALK2 receptor mutants require type II receptor cooperation.

Constitutively activating mutations in receptor kinases recruit downstream effector pathways independently of upstream signaling, with consequences ranging from developmental syndromes to cancer. Classic fibrodysplasia ossificans progressiva (FOP) is a congenital syndrome resulting from highly conserved activating mutations of the glycine-serine-rich (GS) regulatory domain of ACVR1, encoding bone morphogenetic protein (BMP) type I receptor ALK2, which lead to inappropriate signaling and heterotopic ossification of soft tissues. It is unclear if constitutively active mutant ALK2 receptors (caALK2) can function independently of signaling complexes with type II receptors and ligands. We found that ablation of BmpRII and ActRIIa abrogated BMP ligand-mediated and caALK2-mediated signaling and transcription in cells and disrupted caALK2-induced heterotopic ossification in mice. Signaling via GS domain ALK2 mutants could be restored by the expression of either BMP type II receptor. The contribution of BMP type II receptors was independent of their ligand-binding or kinase function but was dependent upon an intact cytoplasmic domain. These data demonstrate that GS domain ALK2 mutants act independently of upstream signaling but may require a nonenzymatic scaffolding function provided by type II receptors to form functional, apparently ligand-independent signaling complexes. These findings define the minimal requirements for signaling of GS domain ALK2 mutants, with implications for the therapeutic targeting of their activity in disease.

BMPs: from bone to body morphogenetic proteins.

The family of bone morphogenetic proteins (BMPs) comprises approximately 30 secreted cytokines that signal through transmembrane serine/threonine kinase receptors. The BMP signaling pathways are fine-tuned on multiple levels: Extracellular antagonists modify ligand activity; several co-receptors enhance or inhibit downstream signaling events through multiple mechanisms; and intracellular molecules further regulate the signaling outcome and mediate crosstalk with other pathways. BMPs affect structures and processes throughout the entire body, ranging from embryonic patterning and development through stem cells and their niches, to tissue homeostasis and regeneration. This comprehensive involvement in various tissues had not been expected by Marshall Urist, who initially discovered the ability of an unknown factor in bone to induce bone growth in muscle and subsequently suggested the name "bone morphogenetic protein." Today, recombinant BMPs are used in clinical practice for the treatment of bone and kidney disorders, and new genetically modified BMPs are emerging as promising tools in regenerative medicine and tissue engineering. Clearly, the functions of BMPs within the body are more versatile than initially suspected. To discuss modern trends in BMP signaling, leaders in the field met for the First International BMP Workshop in Berlin in September 2009. Here, we summarize new insights on the roles of BMPs in various tissues and highlight recent findings in cell, structural, and developmental biology as well as the therapeutic potential of BMPs. Finally, we conclude that BMPs today deserve to be called body morphogenetic proteins.