Literature DB >> 20385559

Characterization of the ligand binding functionality of the extracellular domain of activin receptor type IIb.

Dianne Sako1, Asya V Grinberg, June Liu, Monique V Davies, Roselyne Castonguay, Silas Maniatis, Amy J Andreucci, Eileen G Pobre, Kathleen N Tomkinson, Travis E Monnell, Jeffrey A Ucran, Erik Martinez-Hackert, R Scott Pearsall, Kathryn W Underwood, Jasbir Seehra, Ravindra Kumar.   

Abstract

The single transmembrane domain serine/threonine kinase activin receptor type IIB (ActRIIB) has been proposed to bind key regulators of skeletal muscle mass development, including the ligands GDF-8 (myostatin) and GDF-11 (BMP-11). Here we provide a detailed kinetic characterization of ActRIIB binding to several low and high affinity ligands using a soluble activin receptor type IIB-Fc chimera (ActRIIB.Fc). We show that both GDF-8 and GDF-11 bind the extracellular domain of ActRIIB with affinities comparable with those of activin A, a known high affinity ActRIIB ligand, whereas BMP-2 and BMP-7 affinities for ActRIIB are at least 100-fold lower. Using site-directed mutagenesis, we demonstrate that ActRIIB binds GDF-11 and activin A in different ways such as, for example, substitutions in ActRIIB Leu(79) effectively abolish ActRIIB binding to activin A yet not to GDF-11. Native ActRIIB has four isoforms that differ in the length of the C-terminal portion of their extracellular domains. We demonstrate that the C terminus of the ActRIIB extracellular domain is crucial for maintaining biological activity of the ActRIIB.Fc receptor chimera. In addition, we show that glycosylation of ActRIIB is not required for binding to activin A or GDF-11. Together, our findings reveal binding specificity and activity determinants of the ActRIIB receptor that combine to effect specificity in the activation of distinct signaling pathways.

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Year:  2010        PMID: 20385559      PMCID: PMC2898293          DOI: 10.1074/jbc.M110.114959

Source DB:  PubMed          Journal:  J Biol Chem        ISSN: 0021-9258            Impact factor:   5.157


  41 in total

1.  Regulation of skeletal muscle mass in mice by a new TGF-beta superfamily member.

Authors:  A C McPherron; A M Lawler; S J Lee
Journal:  Nature       Date:  1997-05-01       Impact factor: 49.962

2.  Mutations in myostatin (GDF8) in double-muscled Belgian Blue and Piedmontese cattle.

Authors:  R Kambadur; M Sharma; T P Smith; J J Bass
Journal:  Genome Res       Date:  1997-09       Impact factor: 9.043

3.  Characterization of the extracellular ligand-binding domain of the type II activin receptor.

Authors:  J Greenwald; V Le; A Corrigan; W Fischer; E Komives; W Vale; S Choe
Journal:  Biochemistry       Date:  1998-11-24       Impact factor: 3.162

4.  Determinants of specificity in TGF-beta signal transduction.

Authors:  Y G Chen; A Hata; R S Lo; D Wotton; Y Shi; N Pavletich; J Massagué
Journal:  Genes Dev       Date:  1998-07-15       Impact factor: 11.361

5.  Molecular definition of an allelic series of mutations disrupting the myostatin function and causing double-muscling in cattle.

Authors:  L Grobet; D Poncelet; L J Royo; B Brouwers; D Pirottin; C Michaux; F Ménissier; M Zanotti; S Dunner; M Georges
Journal:  Mamm Genome       Date:  1998-03       Impact factor: 2.957

6.  The unglycosylated extracellular domain of type-II receptor for transforming growth factor-beta. A novel assay for characterizing ligand affinity and specificity.

Authors:  J F Goetschy; O Letourneur; N Cerletti; M A Horisberger
Journal:  Eur J Biochem       Date:  1996-10-15

Review 7.  Molecular and functional characterization of activin receptors.

Authors:  L S Mathews; W W Vale
Journal:  Receptor       Date:  1993

Review 8.  The cystine-knot growth-factor superfamily.

Authors:  P D Sun; D R Davies
Journal:  Annu Rev Biophys Biomol Struct       Date:  1995

9.  The signaling pathway mediated by the type IIB activin receptor controls axial patterning and lateral asymmetry in the mouse.

Authors:  S P Oh; E Li
Journal:  Genes Dev       Date:  1997-07-15       Impact factor: 11.361

10.  Double muscling in cattle due to mutations in the myostatin gene.

Authors:  A C McPherron; S J Lee
Journal:  Proc Natl Acad Sci U S A       Date:  1997-11-11       Impact factor: 11.205
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  57 in total

1.  Loss of BMPR2 leads to high bone mass due to increased osteoblast activity.

Authors:  Jonathan W Lowery; Giuseppe Intini; Laura Gamer; Sutada Lotinun; Valerie S Salazar; Satoshi Ote; Karen Cox; Roland Baron; Vicki Rosen
Journal:  J Cell Sci       Date:  2015-02-06       Impact factor: 5.285

2.  N-linked glycosylation of the bone morphogenetic protein receptor type 2 (BMPR2) enhances ligand binding.

Authors:  Jonathan W Lowery; Jose M Amich; Alex Andonian; Vicki Rosen
Journal:  Cell Mol Life Sci       Date:  2013-12-15       Impact factor: 9.261

3.  Gene expression profiling of skeletal muscles treated with a soluble activin type IIB receptor.

Authors:  Fedik Rahimov; Oliver D King; Leigh C Warsing; Rachel E Powell; Charles P Emerson; Louis M Kunkel; Kathryn R Wagner
Journal:  Physiol Genomics       Date:  2011-01-25       Impact factor: 3.107

4.  Inhibition of myostatin protects against diet-induced obesity by enhancing fatty acid oxidation and promoting a brown adipose phenotype in mice.

Authors:  C Zhang; C McFarlane; S Lokireddy; S Masuda; X Ge; P D Gluckman; M Sharma; R Kambadur
Journal:  Diabetologia       Date:  2011-09-17       Impact factor: 10.122

5.  Structural characterization of an activin class ternary receptor complex reveals a third paradigm for receptor specificity.

Authors:  Erich J Goebel; Richard A Corpina; Cynthia S Hinck; Magdalena Czepnik; Roselyne Castonguay; Rosa Grenha; Angela Boisvert; Gabriella Miklossy; Paul T Fullerton; Martin M Matzuk; Vincent J Idone; Aris N Economides; Ravindra Kumar; Andrew P Hinck; Thomas B Thompson
Journal:  Proc Natl Acad Sci U S A       Date:  2019-07-17       Impact factor: 11.205

6.  Specific targeting of TGF-β family ligands demonstrates distinct roles in the regulation of muscle mass in health and disease.

Authors:  Justin L Chen; Kelly L Walton; Adam Hagg; Timothy D Colgan; Katharine Johnson; Hongwei Qian; Paul Gregorevic; Craig A Harrison
Journal:  Proc Natl Acad Sci U S A       Date:  2017-06-12       Impact factor: 11.205

7.  Myostatin regulates pituitary development and hepatic IGF1.

Authors:  Wioletta Czaja; Yukiko K Nakamura; Naisi Li; Jennifer A Eldridge; David M DeAvila; Thomas B Thompson; Buel D Rodgers
Journal:  Am J Physiol Endocrinol Metab       Date:  2019-03-19       Impact factor: 4.310

8.  Administration of a soluble activin type IIB receptor promotes the transplantation of human myoblasts in dystrophic mice.

Authors:  Raouia Fakhfakh; Se-Jin Lee; Jacques P Tremblay
Journal:  Cell Transplant       Date:  2012       Impact factor: 4.064

9.  Activin-A enhances mTOR signaling to promote aberrant chondrogenesis in fibrodysplasia ossificans progressiva.

Authors:  Kyosuke Hino; Kazuhiko Horigome; Megumi Nishio; Shingo Komura; Sanae Nagata; Chengzhu Zhao; Yonghui Jin; Koichi Kawakami; Yasuhiro Yamada; Akira Ohta; Junya Toguchida; Makoto Ikeya
Journal:  J Clin Invest       Date:  2017-07-31       Impact factor: 14.808

10.  Beyond CDR-grafting: Structure-guided humanization of framework and CDR regions of an anti-myostatin antibody.

Authors:  James R Apgar; Michelle Mader; Rita Agostinelli; Susan Benard; Peter Bialek; Mark Johnson; Yijie Gao; Mark Krebs; Jane Owens; Kevin Parris; Michael St Andre; Kris Svenson; Carl Morris; Lioudmila Tchistiakova
Journal:  MAbs       Date:  2016-09-13       Impact factor: 5.857
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