Designer TGFß superfamily ligands with diversified functionality.

Transforming Growth Factor--beta (TGFß) superfamily ligands, including Activins, Growth and Differentiation Factors (GDFs), and Bone Morphogenetic Proteins (BMPs), are excellent targets for protein-based therapeutics because of their pervasiveness in numerous developmental and cellular processes. We developed a strategy termed RASCH (Random Assembly of Segmental Chimera and Heteromer), to engineer chemically-refoldable TGFß superfamily ligands with unique signaling properties. One of these engineered ligands, AB208, created from Activin-ßA and BMP-2 sequences, exhibits the refolding characteristics of BMP-2 while possessing Activin-like signaling attributes. Further, we find several additional ligands, AB204, AB211, and AB215, which initiate the intracellular Smad1-mediated signaling pathways more strongly than BMP-2 but show no sensitivity to the natural BMP antagonist Noggin unlike natural BMP-2. In another design, incorporation of a short N-terminal segment from BMP-2 was sufficient to enable chemical refolding of BMP-9, without which was never produced nor refolded. Our studies show that the RASCH strategy enables us to expand the functional repertoire of TGFß superfamily ligands through development of novel chimeric TGFß ligands with diverse biological and clinical values.

Bone morphogenetic protein-2 and -6 heterodimer illustrates the nature of ligand-receptor assembly.

TGF-beta superfamily ligands are homo- or heterodimeric and recruit two type I and two type II Ser/Thr kinase receptors to initiate a transmembrane signaling cascade. Even with the known structure of the homodimer ligands in complex with extracellular domains of both receptor types, the sequential assembly of the signaling complex with its cognate receptors in the cell membrane remains elusive. We generated a bone morphogenetic protein-2/-6 heterodimer carrying two asymmetric interfaces for each receptor type. We demonstrate that the heterodimer possesses high affinity to both receptor types and increased Smad1-dependent signaling activity by both cell-based and chondrogenesis assays. Furthermore, we find that the minimal signaling complex consists of two type II receptors and one type I receptor per dimer. Our study reveals how the engineered heterodimers may use their independent binding interfaces to differentially recruit the different receptors for each receptor type to create new biological properties.

Neogenin interacts with hemojuvelin through its two membrane-proximal fibronectin type III domains.

Hemojuvelin is a recently identified iron-regulatory protein that plays an important role in affecting the expression of hepcidin, a key iron regulatory hormone. Although the underlying mechanism of this process is not clear, several hemojuvelin-binding proteins, including the cell surface receptor neogenin and bone morphogenetic protein (BMP) cytokines, have been identified. The ectodomain of neogenin is composed of four immunoglobulin-like (Ig) domains followed by six fibronectin type III-like (FNIII) domains. Here we report expression of soluble versions of hemojuvelin and neogenin for biochemical characterization of their interaction and the interaction of HJV with BMP-2. Hemojuvelin normally undergoes an autocatalytic cleavage, and as in vivo, recombinant hemojuvelin exists as a mixture of cleaved and uncleaved forms. Neogenin binds to cleaved and noncleaved hemojuvelin, as verified by its binding to an uncleaved mutant hemojuvelin. We localized the hemojuvelin binding site on neogenin to the membrane-proximal fifth and sixth FNIII domains and the juxtamembrane linker and showed that a fragment containing only this region binds 2-3 orders of magnitude more tightly than the entire neogenin ectodomain. Binding to the most membrane-proximal region of neogenin may play a role in regulating the levels of soluble and membrane-bound forms of hemojuvelin, which in turn would influence the amount of free BMP-2 available for binding to its receptors and triggering transcription of the hepcidin gene. Our finding that BMP-2 and neogenin bind simultaneously to hemojuvelin raises the possibility that neogenin is part of a multiprotein complex at the hepatocyte membrane involving BMP, its receptors, and hemojuvelin.

BMP-3 and BMP-6 structures illuminate the nature of binding specificity with receptors.

Bone morphogenetic proteins (BMPs) are extracellular messenger ligands involved in controlling a wide array of developmental and intercellular signaling processes. To initiate their specific intracellular signaling pathways, the ligands recognize and bind two structurally related serine/threonine kinase receptors, termed type I and type II, on the cell surface. Here, we present the crystal structures of BMP-3 and BMP-6, of which BMP-3 has remained poorly understood with respect to its receptor identity, affinity, and specificity. Using surface plasmon resonance (BIAcore) we show that BMP-3 binds Activin Receptor type II (ActRII) with Kd approximately 1.8 microM but ActRIIb with 30-fold higher affinity at Kd approximately 53 nM. This low affinity for ActRII may involve Ser-28 and Asp-33 of BMP-3, which are found only in BMP-3's type II receptor-binding interfaces. Point mutations of either residue to alanine results in up to 20-fold higher affinity to either receptor. We further demonstrate by Smad-based whole cell luciferase assays that the increased affinity of BMP-3S28A to ActRII enables the ligand's signaling ability to a level comparable to that of BMP-6. Focusing on BMP-3's preference for ActRIIb, we find that Lys-76 of ActRII and the structurally equivalent Glu-76 of ActRIIb are distinct between the two receptors. We demonstrate that ActRIIbE76K and ActRII bind BMP-3 with similar affinity, indicating BMP-3 receptor specificity is controlled by the interaction of Lys-30 of BMP-3 with Glu-76 of ActRIIb. These studies illustrate how a single amino acid can regulate the specificity of ligand-receptor binding and potentially alter biological signaling and function in vivo.

Structure of the ternary signaling complex of a TGF-beta superfamily member.

The crystal structure of the complete signaling complex formed between bone morphogenetic protein 2 (BMP-2) and the extracellular domains (ECDs) of its type I receptor [bone morphogenetic protein receptor type Ia (BMPR-Ia)-ECD] and its type II receptor [activin receptor type II (ActRII)-ECD] shows two fundamental structural constraints for receptor assembly. First, the homodimeric BMP-2 ligand assembles two pairs of each receptor symmetrically, where each of the receptor ECDs does not make physical contact. Therefore, conformational communication between receptor ECDs, if any, should be propagated through the central ligand. Second, the type I and II receptor interfaces of the complex, when compared with those of binary complexes such as BMP-2/BMPR Ia-ECD, BMP-7/ActRII-ECD, and activin/ActRIIb-ECD, respectively, show there are common sets of positions repeatedly used by both ligands and receptors. Therefore, specificity-determining amino acid differences at the receptor interfaces should also account for the disparity in affinity of individual receptors for different ligand subunits. We find that a specific mutation to BMP-2 increases its affinity to ActRII-ECD by 5-fold. These results together establish that the specific signaling output is largely determined by two variables, the ligand-receptor pair identity and the mode of cooperative assembly of relevant receptors governed by the ligand flexibility in a membrane-restricted manner.

A flexible activin explains the membrane-dependent cooperative assembly of TGF-beta family receptors.

A new crystal structure of activin in complex with the extracellular domain of its type II receptor (ActRIIb-ECD) shows that the ligand exhibits an unexpected flexibility. The motion in the activin dimer disrupts its type I receptor interface, which may account for the disparity in its affinity for type I versus type II receptors. We have measured the affinities of activin and its antagonist inhibin for ActRIIb-ECD and found that the affinity of the 2-fold symmetric homodimer activin for ActRIIb-ECD depends on the availability of two spatially coupled ActRIIb-ECD molecules, whereas the affinity of the heterodimer inhibin does not. Our results indicate that activin's affinity for its two receptor types is greatly influenced by their membrane-restricted setting. We propose that activin affinity is modulated by the ligand flexibility and that cooperativity is achieved by binding to two ActRII chains that immobilize activin in a type I binding-competent orientation.