Difference between revisions of "Developmental Signals - Bone Morphogenetic Protein"
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! Gene abbreviation
! Gene Location
! Gene Location
Revision as of 18:09, 23 October 2018
|Embryology - 18 Nov 2019 Expand to Translate|
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العربية | català | 中文 | 中國傳統的 | français | Deutsche | עִברִית | हिंदी | bahasa Indonesia | italiano | 日本語 | 한국어 | မြန်မာ | Pilipino | Polskie | português | ਪੰਜਾਬੀ ਦੇ | Română | русский | Español | Swahili | Svensk | ไทย | Türkçe | اردو | ייִדיש | Tiếng Việt These external translations are automated and may not be accurate. (More? About Translations)
- 1 Introduction
- 2 Some Recent Findings
- 3 Human BMP Family
- 4 Structure
- 5 Function
- 6 Signaling Pathway
- 7 Additional Images
- 8 OMIM
- 9 Abnormalities
- 10 References
- 11 External Links
- 12 Glossary Links
Belongs to the transforming growth factor-beta (TGFB) superfamily, humans have 15 members in this protein signaling family. The proteins are synthesized as prepropeptides, then cleaved, and processed into dimeric proteins.
- TGFB family members: TGFB1, TGFB, TGFB3, bone morphogenetic proteins Bmp-2A, Bmp-2B, Bmp-3, and Bmp-6. mullerian inhibitory substance.
Mouse Bmp4 expression face.
- BMP Mouse Links: Face and limb E9.5-13.5 | Face E9.5-13.5 | Body E11.0 | Body E11.5 | BMP | Mouse Development
Growth Differentiation Factor-6 (Gdf6) is a member of the Bone Morphogenetic Protein (BMP) family of secreted signaling molecules.
|Factor Links: AMH | hCG | BMP | sonic hedgehog | bHLH | HOX | FGF | FOX | Hippo | LIM | Nanog | NGF | Nodal | Notch | PAX | retinoic acid | SIX | Slit2/Robo1 | SOX | TBX | TGF-beta | VEGF | WNT | Category:Molecular|
Some Recent Findings
|More recent papers|
This table allows an automated computer search of the external PubMed database using the listed "Search term" text link.
Search term: Bone Morphogenetic Protein
<pubmed limit=5>Bone Morphogenetic Protein</pubmed>
Human BMP Family
|Table - Human Bmp Family|
|BMP1||bone morphogenetic protein 1||PCOLC||8p21.3|
|BMP2||bone morphogenetic protein 2||BMP2A||20p12.3|
|BMP3||bone morphogenetic protein 3||4q21.21|
|BMP4||bone morphogenetic protein 4||BMP2B||14q22.2|
|BMP5||bone morphogenetic protein 5||6p12.1|
|BMP6||bone morphogenetic protein 6||VGR||VGR1||6p24.3|
|BMP7||bone morphogenetic protein 7||OP-1||20q13.31|
|BMP8A||bone morphogenetic protein 8a||1p34.3|
|BMP8B||bone morphogenetic protein 8b||BMP8||OP-2||1p34.2|
|BMP10||bone morphogenetic protein 10||2p13.3|
|BMP15||bone morphogenetic protein 15||GDF9B||Xp11.22|
|Links: Developmental Signals - Bone Morphogenetic Protein | OMIM BMP2 | HGNC | Bmp Family | Sox Family | Tbx Family|
|Human BMP Family|
|BMP Superfamily Canonical Signalling|
|Over 30 bone morphogenetic protein (BMP) superfamily ligands have been discovered in humans. Most are secreted as mature disulfide-linked dimers, with the exception of TGF-β1, TGF-β2 and TGF-β3, which can be secreted in a latent form and require proteolytic activation. BMPs signal through a multimeric cell surface complex consisting of two type I receptors and two type II receptors.
Activated type I receptors recruit and phosphorylate pathway-specific R-SMADs (SMAD1, SMAD5 and SMAD8 (blue pathway), and SMAD2 and SMAD3 (orange pathway)), which can form trimers with SMAD4 and translocate to the nucleus. SMADs have intrinsic DNA-binding activity and are able to regulate gene expression by recruitment of chromatin-remodelling machinery and integration with tissue-specific transcription factors. SMAD8 is also known as SMAD9.
The pathway can be antagonized by many mechanisms including neutralization of ligands by secreted traps such as noggin or follistatin, secretion of latent ligands bound to their propeptides, or via titration of receptors by nonsignalling ligands such as BMP3, activin β/inhibin α dimers or LEFTY monomers.
Mouse Bmp4 expression limb and face.
During gastrulation the BMP pathway is antagonised and involved with neural induction. Neural induction signaling through the BMP-regulated Smad1/5 proteins appears to be controlled by fibroblast growth factor (FGF)-regulated Ca2+ entry activating calcineurin (CaN) that in turn dephosphorylates Smad1/5 proteins.
- Links: Neural Development
|Molecular paracrine interactions involving BMP15 signaling||Localization of BMP15 in calf and cow follicles|
- Links: Oocyte Development
Bmp2, Bmp4 and Bmp7 are co-required in the mouse AER for normal digit patterning but not limb outgrowth
- "Outgrowth and patterning of the vertebrate limb requires a functional apical ectodermal ridge (AER). The AER is a thickening of ectodermal tissue located at the distal end of the limb bud. Loss of this structure, either through genetic or physical manipulations results in truncation of the limb. A number of genes, including Bmps, are expressed in the AER. Previously, it was shown that removal of the BMP receptor Bmpr1a specifically from the AER resulted in complete loss of hindlimbs suggesting that Bmp signaling in the AER is required for limb outgrowth. In this report, we genetically removed the three known AER-expressed Bmp ligands, Bmp2, Bmp4 and Bmp7 from the AER of the limb bud using floxed conditional alleles and the Msx2-cre allele. Surprisingly, only defects in digit patterning and not limb outgrowth were observed. In triple mutants, the anterior and posterior AER was present but loss of the central region of the AER was observed. These data suggest that Bmp ligands expressed in the AER are not required for limb outgrowth but instead play an essential role in maintaining the AER and patterning vertebrate digits."
- Links: Limb Development
Blood Vessel Development
BMP/SMAD signaling pathway regulates angiogenic sprouting and is involved in embryo vascular development.
Identified BMP modulators: Noggin, Chordin, Chordin-like 1, Chordin-like 2, Twisted gastrulation, Dan, BMPER, Sost, Sostdc1, Follistatin, Follistatin-like 1, Follistatin-like 5 and Tolloid.
SNW-domain containing protein 1
(SNW1, SKI-INTERACTING PROTEIN; SKIIP)
A protein that interacts with nuclear receptors and enhances ligand-activated transcription, also called a nuclear receptor co-activator.
Regulator of Spatial BMP Activity, Neural Plate Border Formation, and Neural Crest Specification in Vertebrate Embryos
- "Bone morphogenetic protein (BMP) gradients provide positional information to direct cell fate specification, such as patterning of the vertebrate ectoderm into neural, neural crest, and epidermal tissues, with precise borders segregating these domains. However, little is known about how BMP activity is regulated spatially and temporally during vertebrate development to contribute to embryonic patterning, and more specifically to neural crest formation. Through a large-scale in vivo functional screen in Xenopus for neural crest fate, we identified an essential regulator of BMP activity, SNW1. SNW1 is a nuclear protein known to regulate gene expression. Using antisense morpholinos to deplete SNW1 protein in both Xenopus and zebrafish embryos, we demonstrate that dorsally expressed SNW1 is required for neural crest specification, and this is independent of mesoderm formation and gastrulation morphogenetic movements. By exploiting a combination of immunostaining for phosphorylated Smad1 in Xenopus embryos and a BMP-dependent reporter transgenic zebrafish line, we show that SNW1 regulates a specific domain of BMP activity in the dorsal ectoderm at the neural plate border at post-gastrula stages. We use double in situ hybridizations and immunofluorescence to show how this domain of BMP activity is spatially positioned relative to the neural crest domain and that of SNW1 expression. Further in vivo and in vitro assays using cell culture and tissue explants allow us to conclude that SNW1 acts upstream of the BMP receptors. Finally, we show that the requirement of SNW1 for neural crest specification is through its ability to regulate BMP activity, as we demonstrate that targeted overexpression of BMP to the neural plate border is sufficient to restore neural crest formation in Xenopus SNW1 morphants. We conclude that through its ability to regulate a specific domain of BMP activity in the vertebrate embryo, SNW1 is a critical regulator of neural plate border formation and thus neural crest specification."
About OMIM "Online Mendelian Inheritance in Man OMIM is a comprehensive, authoritative, and timely compendium of human genes and genetic phenotypes. The full-text, referenced overviews in OMIM contain information on all known mendelian disorders and over 12,000 genes. OMIM focuses on the relationship between phenotype and genotype. It is updated daily, and the entries contain copious links to other genetics resources." OMIM
- Links: OMIM300247
|Name||Gene Location||Online Mendelian
Inheritance in Man (OMIM)
|HUGO Gene Nomenclature
|BMP15||Bone morphogenetic protein 15||Xp11.22||300247||1068||GC0XP050910||Primary ovarian insufficiency|
| Table data source (table 1) Links: fertilization | oocyte | ovary | | Female Infertility Genes | spermatozoa | testis | Male Infertility Genes | Genetic Abnormalities | ART|
Primary ovarian insufficiency - depletion or dysfunction of ovarian follicles with cessation of menses before age 40 years.
|Female Infertility Genes|
- Jumlongras D, Lachke SA, O'Connell DJ, Aboukhalil A, Li X, Choe SE, Ho JW, Turbe-Doan A, Robertson EA, Olsen BR, Bulyk ML, Amendt BA & Maas RL. (2012). An evolutionarily conserved enhancer regulates Bmp4 expression in developing incisor and limb bud. PLoS ONE , 7, e38568. PMID: 22701669 DOI.
- Row RH, Pegg A, Kinney B, Farr GH, Maves L, Lowell S, Wilson V & Martin BL. (2018). BMP and FGF signaling interact to pattern mesoderm by controlling basic helix-loop-helix transcription factor activity. Elife , 7, . PMID: 29877796 DOI.
- Mimura S, Suga M, Okada K, Kinehara M, Nikawa H & Furue MK. (2016). Bone morphogenetic protein 4 promotes craniofacial neural crest induction from human pluripotent stem cells. Int. J. Dev. Biol. , 60, 21-8. PMID: 26934293 DOI.
- Bier E & De Robertis EM. (2015). EMBRYO DEVELOPMENT. BMP gradients: A paradigm for morphogen-mediated developmental patterning. Science , 348, aaa5838. PMID: 26113727 DOI.
- Xu PF, Houssin N, Ferri-Lagneau KF, Thisse B & Thisse C. (2014). Construction of a vertebrate embryo from two opposing morphogen gradients. Science , 344, 87-9. PMID: 24700857 DOI.
- Miletich I, Yu WY, Zhang R, Yang K, Caixeta de Andrade S, Pereira SF, Ohazama A, Mock OB, Buchner G, Sealby J, Webster Z, Zhao M, Bei M & Sharpe PT. (2011). Developmental stalling and organ-autonomous regulation of morphogenesis. Proc. Natl. Acad. Sci. U.S.A. , 108, 19270-5. PMID: 22084104 DOI.
- Salazar VS, Gamer LW & Rosen V. (2016). BMP signalling in skeletal development, disease and repair. Nat Rev Endocrinol , 12, 203-21. PMID: 26893264 DOI.
- Cho A, Tang Y, Davila J, Deng S, Chen L, Miller E, Wernig M & Graef IA. (2014). Calcineurin signaling regulates neural induction through antagonizing the BMP pathway. Neuron , 82, 109-124. PMID: 24698271 DOI.
- Chronowska E. (2014). High-throughput analysis of ovarian granulosa cell transcriptome. Biomed Res Int , 2014, 213570. PMID: 24711992 DOI.
- Hosoe M, Kaneyama K, Ushizawa K, Hayashi KG & Takahashi T. (2011). Quantitative analysis of bone morphogenetic protein 15 (BMP15) and growth differentiation factor 9 (GDF9) gene expression in calf and adult bovine ovaries. Reprod. Biol. Endocrinol. , 9, 33. PMID: 21401961 DOI.
- Choi KS, Lee C, Maatouk DM & Harfe BD. (2012). Bmp2, Bmp4 and Bmp7 are co-required in the mouse AER for normal digit patterning but not limb outgrowth. PLoS ONE , 7, e37826. PMID: 22662233 DOI.
- Lorda-Diez CI, Montero JA, Rodriguez-Leon J, Garcia-Porrero JA & Hurle JM. (2013). Expression and functional study of extracellular BMP antagonists during the morphogenesis of the digits and their associated connective tissues. PLoS ONE , 8, e60423. PMID: 23573253 DOI.
- Wu MY, Ramel MC, Howell M & Hill CS. (2011). SNW1 is a critical regulator of spatial BMP activity, neural plate border formation, and neural crest specification in vertebrate embryos. PLoS Biol. , 9, e1000593. PMID: 21358802 DOI.
- Harper JC, Aittomäki K, Borry P, Cornel MC, de Wert G, Dondorp W, Geraedts J, Gianaroli L, Ketterson K, Liebaers I, Lundin K, Mertes H, Morris M, Pennings G, Sermon K, Spits C, Soini S, van Montfoort APA, Veiga A, Vermeesch JR, Viville S & Macek M. (2018). Recent developments in genetics and medically assisted reproduction: from research to clinical applications. Eur. J. Hum. Genet. , 26, 12-33. PMID: 29199274 DOI.
Cho A, Tang Y, Davila J, Deng S, Chen L, Miller E, Wernig M & Graef IA. (2014). Calcineurin signaling regulates neural induction through antagonizing the BMP pathway. Neuron , 82, 109-124. PMID: 24698271 DOI.
Kuypers E, Collins JJ, Jellema RK, Wolfs TG, Kemp MW, Nitsos I, Pillow JJ, Polglase GR, Newnham JP, Germeraad WT, Kallapur SG, Jobe AH & Kramer BW. (2012). Ovine fetal thymus response to lipopolysaccharide-induced chorioamnionitis and antenatal corticosteroids. PLoS ONE , 7, e38257. PMID: 22693607 DOI.
- Molecular Biology of the Cell. 4th edition. Alberts B, Johnson A, Lewis J, et al.New York: Garland Science; 2002. Signal Proteins of the TGF-β Superfamily Act Through Receptor Serine/Threonine Kinases and Smads
- Madame Curie Bioscience Database (Internet). Austin (TX): Landes Bioscience; 2000. TGFβ-dependent Epithelial-Mesenchymal Transition
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- NCBI - Mouse BMP4 gene
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Cite this page: Hill, M.A. (2019, November 18) Embryology Developmental Signals - Bone Morphogenetic Protein. Retrieved from https://embryology.med.unsw.edu.au/embryology/index.php/Developmental_Signals_-_Bone_Morphogenetic_Protein
- © Dr Mark Hill 2019, UNSW Embryology ISBN: 978 0 7334 2609 4 - UNSW CRICOS Provider Code No. 00098G