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Growth hormone-binding protein

From Wikipedia, the free encyclopedia
growth hormone receptor
Identifiers
SymbolGHR
NCBI gene2690
HGNC4263
OMIM600946
RefSeqNM_000163
UniProtP10912
Other data
LocusChr. 5 p13-p12
Search for
StructuresSwiss-model
DomainsInterPro

Growth hormone-binding protein (GHBP) is a soluble carrier protein for growth hormone (GH).[1] The full range of functions of GHBP remains to be determined.[2][3] However, current research suggests that the protein is associated with regulation of the GH availability and half-life in the circulatory system, as well as modulating GH receptor function.[4]

Expression

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In humans, GHBP is formed by post-translational modification after the complete transcription and translation of the growth hormone receptor (GHR) gene into the cell-surface receptor protein. The gene that codes for GHR (and inherently GHBP) is on Chromosome 5.[5] A precursor messenger RNA (mRNA) from the complete gene first is transcribed and then spliced to encode the full receptor protein. This mature mRNA is composed of exons. Exons are peptide encoding regions of DNA genes that remain in the transcript after splicing and during the maturation of mRNA. The mRNA transcript encodes for a receptor protein that is made up of three distinct parts: an intracellular domain, a transmembrane domain, and an extracellular domain.[6] Specifically, part of exon 2 and exons 3-7 of the GHR gene will translate to amino acids that make up the extracellular domain of GHR. This extracellular domain physically binds GH in the receptor-ligand interaction.[4]

"Receptor Ectodomain Shedding" - Tumor-necrosis factor alpha converting enzyme (T.A.C.E.) proteolytically cleaves the extracellular domain off of (two) growth hormone receptor(s) to release the soluble carrier-protein growth hormone-binding protein. Adapted from Fisker.[7]

In rodents and in humans the concentration GHR mRNA and the concentration of GHBP in the maternal circulation are dramatically increased during pregnancy.[8][9] This is considered likely to control the availability of GH for binding to GH receptors in the maternal tissues during pregnancy.[10]

Receptor ectodomain shedding

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When the extracellular domain of GHR is proteolytically cleaved (see: proteolytic cleavage) from the rest of the receptor protein, the extracellular domain is released as the water-soluble, carrier protein GHBP.[11][12][13] As the extracellular domain alone, the polypeptide consists of 246 amino acids[4] and is roughly 60 kDA in size.[14] This cleaving process is called “receptor ectodomain shedding.[15] In humans and rabbits, tumor-necrosis factor alpha converting enzyme (T.A.C.E.) is postulated to play a significant role in the post-translational processing activity that sheds GHBP from GHR.[16][17] Studies show that this activity primarily occurs in the liver.[18] When growth hormone is bound to two dimerized GH receptors, the shedding activity is inhibited. This occurs because when the ligand binds to the receptors, a conformational change occurs in them that potentially blocks the proteolytic activity of T.A.C.E.[17][19]

Alternative splicing

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In humans, studies have shown that alternative splicing of the GHR gene can lead to increased rates of proteolysis. For example, a deletion within the mRNA that encodes part of the transmembrane domain of the protein effectively leads to non-translation of the intracellular domain due to the presence of a stop codon.[20] This truncated version of GHR is cleaved more frequently into GHBP and may potentially explain the reasoning behind increased concentrations of GHBP present in some tissues.[21]

In mouse and rat models, the extracellular domain is formed primarily through alternative splicing of the precursor GHR mRNA to form a mature transcript that translate GHBP alone. These animals can potentially shed GHBP via post-translational modification as well, although this activity is minimal.[17][22]

Function

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Two growth hormone-binding proteins (blue, pink) in a two-to-one ratio with growth hormone (green). Source: PDB 1HWG

The full range of physiological consequences of GHBP binding GH is not known ,[23] however literature provides evidence that the carrier-protein prolongs the half-life of growth hormone through its binding with the ligand.[24]

Binding stoichiometry

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Growth hormone binds to GHBP and GHR via an interactive region of helices 1 and 4 of GH.[25] Two receptor molecules are pre-dimerized upon GH binding, so it always binds in a 1:2 ratio.[26] Assays estimate that growth hormone and growth hormone binding protein form a natural complex at a 1:1 ratio for transport and preservation of the ligand through the bloodstream.[27][28] However, some sources have shown that high physiological concentration of GHBP will result in a 1:2 ratio.[29][30] When the cysteine amino acids in GHBP are mutated and the disulfide bridges are disrupted, the ability of the ligand to bind to the active site of the GHBP is significantly lessened.[31]

Activation

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Growth-hormone binding protein (blue) in a one-to-one ratio with modified growth hormone (green). Source: PDB 1HWH

The clearance rate, or the rate at which the carrier protein is broken down, for GHBP alone is much faster than when it is bound to its ligand.[4] Additionally, current literature provides evidence that the carrier-protein prolongs the half-life of growth hormone through its binding with the ligand.[24] One purpose of GHBP can be inferred: to maintain the level of GH in the blood, as roughly half of its concentration is complexed with GHBP.[32] Yet this could be confounded by the fact that GH binding to GHBP prevents the ligand from binding to GHR and ultimately proteolytic activity.[33] Another function is that GHBP displays competitive inhibition for GH against the GHR receptor.[18]

Studies elucidate another aspect of GHBP physiological role: The proteolytic cleavage activity that forms GHBP ultimately regulates GHR production in humans as well as rats.[19][34] If there is low GHBP concentration then there are high levels of GHR expression. Conversely, high levels of GHBP protein show negative correlation with levels of growth hormone receptor expression.[18][35]

Isoforms

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Exon 3

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Studies have identified a GHBP isoform that exists due to gene polymorphism, or variable expression of the allele. These isoforms differ based on whether or not the extracellular domain of GHR includes the amino acids encoded by exon 3 - exon 3 is either kept (dominant) or spliced out (recessive).[36] As human are diploid, they may genotype as homozygous dominant (two copies of the allele retain exon 3), heterozygous (one copy with Exon 3, and one without), or homozygous recessive (two copies of the allele without exon 3).[37] Studies have shown that the two isoforms can co-exist as dimerized GH receptors, as E3+/E3+, E3+/E3-, or E3-/E3-.[36]

Furthermore, the two isoforms both exist in the blood as GHBP. However, they may have separate functions that are poorly understood. The presence or absence of exon 3 in humans is individual-specific, but one study suggests that gender may play a role in this variable splicing, as females were shown to express higher levels of deleted-exon 3 GHBP in their blood.[38] The evolutionary reason for exon-3 variable GHBP expression has not clearly be defined, and the isoforms in the blood have not been shown to differ with respect to GH affinity, which is unusual for an isoform that is missing an entire exon.[39]

References

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  1. ^ Baumann G (Dec 2002). "Growth hormone binding protein. The soluble growth hormone receptor". Minerva Endocrinologica. 27 (4): 265–76. PMID 12511849.
  2. ^ Baumann G, Stolar MW, Amburn K, Barsano CP, DeVries BC (Jan 1986). "A specific growth hormone-binding protein in human plasma: initial characterization". The Journal of Clinical Endocrinology and Metabolism. 62 (1): 134–41. doi:10.1210/jcem-62-1-134. PMID 3940261.
  3. ^ Baumann G (1999). "Growth Hormone Binding Proteins". In Bengtsson BÅ (ed.). Growth Hormone. Endocrine Updates. Vol. 4. Springer. pp. 37–57. doi:10.1007/978-1-4615-5163-8_3. ISBN 978-1-4613-7351-3.
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  6. ^ "GHR growth hormone receptor [Homo sapiens (human)]". NCBI.
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  20. ^ Ross RJ, Esposito N, Shen XY, Von Laue S, Chew SL, Dobson PR, Postel-Vinay MC, Finidori J (Mar 1997). "A short isoform of the human growth hormone receptor functions as a dominant negative inhibitor of the full-length receptor and generates large amounts of binding protein". Molecular Endocrinology. 11 (3): 265–73. doi:10.1210/mend.11.3.9901. PMID 9058373.
  21. ^ Iida K, Takahashi Y, Kaji H, Nose O, Okimura Y, Abe H, Chihara K (1998). "Growth hormone (GH) insensitivity syndrome with high serum GH-binding protein levels caused by a heterozygous splice site mutation of the GH receptor gene producing a lack of intracellular domain". The Journal of Clinical Endocrinology and Metabolism. 83 (2): 531–7. doi:10.1210/jcem.83.2.4601. PMID 9467570.
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  24. ^ a b Carlsson LM, Rosberg S, Vitangcol RV, Wong WL, Albertsson-Wikland K (Aug 1993). "Analysis of 24-hour plasma profiles of growth hormone (GH)-binding protein, GH/GH-binding protein-complex, and GH in healthy children". The Journal of Clinical Endocrinology and Metabolism. 77 (2): 356–61. doi:10.1210/jcem.77.2.8345039. PMID 8345039.
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  30. ^ de Vos AM, Ultsch M, Kossiakoff AA (Jan 1992). "Human growth hormone and extracellular domain of its receptor: crystal structure of the complex". Science. 255 (5042): 306–12. Bibcode:1992Sci...255..306D. doi:10.1126/science.1549776. PMID 1549776.
  31. ^ Junnila RK, Wu Z, Strasburger CJ. The role of human growth hormone's C-terminal disulfide bridge. Growth Horm IGF Res. 2013;23(3):62-7
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  36. ^ a b Stallings-Mann ML, Ludwiczak RL, Klinger KW, Rottman F (Oct 1996). "Alternative splicing of exon 3 of the human growth hormone receptor is the result of an unusual genetic polymorphism". Proceedings of the National Academy of Sciences of the United States of America. 93 (22): 12394–9. Bibcode:1996PNAS...9312394S. doi:10.1073/pnas.93.22.12394. PMC 38002. PMID 8901592.
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  39. ^ Kucukhuseyin O, Toptas B, Timirci-Kahraman O, Isbir S, Karsidag K, Isbir T (2015-06-01). "The Effect of GHR/exon-3 Polymorphism and Serum GH, IGF-1 and IGFBP-3 Levels in Diabetes and Coronary Heart Disease". In Vivo. 29 (3): 371–8. PMID 25977383.
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