CDB25:0003804 INHBA — BMPR2
Experimentally validated in Human; Orthology-inferred in Mouse, Rat, Frog, Zebrafish, Chicken, Macaque, Pig, Dog, Cow, Chimp, Horse, Marmoset, Sheep
Title
Journal:; Year Published:
Abstract
Inhibin is an antagonist of bone morphogenetic protein signaling.
The Journal of biological chemistry, 2003; PubMed, Homo sapiens INHBA — Homo sapiens BMPR2
ABSTRACT: Inhibins are endogenous antagonists of activin signaling, long recognized as important regulators of gonadal function and pituitary FSH release. Inhibin, in concert with its co-receptor, betaglycan, can compete with activin for binding to type II activin receptors and, thus, prevent activin signaling. Because bone morphogenetic proteins (BMPs) also utilize type II activin receptors, we hypothesized that BMP signaling might also be sensitive to inhibin blockade. Here we show that inhibin blocks cellular responses to diverse BMP family members in a variety of BMP-responsive cell types. Inhibin abrogates BMP-induced Smad signaling and transcription responses. Inhibin competes with BMPs for type II activin receptors, and this competition is facilitated by betaglycan. Betaglycan also enables inhibin to bind to and compete with BMPs for binding to the BMP-specific type II receptor BMPRII, which does not bind inhibin in the absence of betaglycan. Betaglycan can confer inhibin responsiveness on cells that are otherwise insensitive to inhibin. These findings demonstrate that inhibin, acting through betaglycan, can function as an antagonist of BMP responses, suggesting a broader role for inhibin and betaglycan in restricting and refining a wide spectrum of transforming growth factor beta superfamily signals.
Type II BMP and activin receptors BMPR2 and ACVR2A share a conserved mode of growth factor recognition.
The Journal of biological chemistry, 2022; PubMed, Homo sapiens INHBA — Homo sapiens BMPR2
ABSTRACT: BMPR2 is a type II Transforming Growth Factor (TGF)-β family receptor that is fundamentally associated with pulmonary arterial hypertension (PAH) in humans. BMPR2 shares functional similarities with the type II activin receptors ACVR2A and ACVR2B, as it interacts with an overlapping group of TGF-β family growth factors (GFs). However, how BMPR2 recognizes GFs remains poorly understood. Here, we solved crystal structures of BMPR2 in complex with the GF activin B and of ACVR2A in complex with the related GF activin A. We show that both BMPR2 and ACVR2A bind GFs with nearly identical geometry using a conserved hydrophobic hot spot, while differences in contacting residues are predominantly found in loop areas. Upon further exploration of the GF-binding spectrum of the two receptors, we found that although many GFs bind both receptors, the high-affinity BMPR2 GFs comprise BMP15, BMP10, and Nodal, whereas those of ACVR2A are activin A, activin B, and GDF11. Lastly, we evaluated GF-binding domain BMPR2 variants found in human PAH patients. We demonstrate that mutations within the GF-binding interface resulted in loss of GF binding, while mutations in loop areas allowed BMPR2 to retain the ability to bind cognate GFs with high affinity. In conclusion, the in vitro activities of BMPR2 variants and the crystal structures reported here indicate biochemically relevant complexes that explain how some GF-binding domain variants can lead to PAH.