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Calcium-sensing receptor

Summary

The calcium-sensing receptor (CaSR) is a Class C G-protein coupled receptor which senses extracellular levels of calcium ions. It is primarily expressed in the parathyroid gland, the renal tubules of the kidney and the brain.[5][6] In the parathyroid gland, it controls calcium homeostasis by regulating the release of parathyroid hormone (PTH).[7] In the kidney it has an inhibitory effect on the reabsorption of calcium, potassium, sodium, and water depending on which segment of the tubule is being activated.[8]

CASR
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
AliasesCASR, CAR, EIG8, FHH, FIH, GPRC2A, HHC, HHC1, HYPOC1, NSHPT, PCAR1, calcium sensing receptor, hCasR, Calcium-sensing receptor+CaSR
External IDsOMIM: 601199 MGI: 1351351 HomoloGene: 332 GeneCards: CASR
Orthologs
SpeciesHumanMouse
Entrez

846

12374

Ensembl

ENSG00000036828

ENSMUSG00000051980

UniProt

P41180

Q9QY96

RefSeq (mRNA)

NM_000388
NM_001178065

NM_013803

RefSeq (protein)

NP_000379
NP_001171536

NP_038831

Location (UCSC)Chr 3: 122.18 – 122.29 MbChr 16: 36.31 – 36.38 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Since the initial review of CaSR,[9] there has been in-depth analysis of its role related to parathyroid disease and other roles related to tissues and organs in the body. 1993, Brown et al.[10] isolated a clone named BoPCaR (bovine parathyroid calcium receptor) which replicated the effect when introduced to polyvalent cations. Because of this, the ability to clone full-length CaSRs from mammals were performed.[11]

Structure edit

Each protomer of the receptor has a large, N-terminal extracellular domain that linked to create VFT (Venus flytrap) domain. The receptor has a CR (cysteine-rich) domain that links the VFT to the 7 transmembrane domains of the receptor. The 7 transmembrane domain is followed by a long cytoplasmatic tail. The tail has no structure, but still, it has an important role in trafficking and phosphorylation.[12]

The CaSR is a homodimer receptor. The signal transmission occurs only when the agonist binds to the homodimer of the CaSR. Binding of a single protomer will not lead to signal transmission. In vitro experiments showed that the receptor can form a heterodimer with mGlu1/5 or with GABAB receptor. The heterodimerization may facilitate the varied functional roles of the CaSR in different tissues, particularly in the brain.

The CryoEM structures of CasR homodimer was recentlly solved

Calcium-Sensing Receptor Extracellular Domain edit

The VFT extends outside the cell and is composed of two lobe subdomains. Each lobe forms part of the ligand binding cleft.

In contrast to the conservative structure of other class C GPCR receptors, the CaSR cleft is an allosteric or co-agonist binding site, with the cations (Ca2+) binding elsewhere.

The inactive state of the receptor has two extracellular domains, oriented in an open conformation with an empty intradomain part. When the receptor is activated, the two lobes interact with each other and creates a rotation of the interdomain cleft.[13]

Cation Binding Sites edit

The cation binding sites varied in their location and in the number of repetitive appearances.[13]

The receptor has four Calcium binding sites that have a role in the stabilization[13] of the extracellular domain (ECD) and in the activation of the receptor. The stabilization maintains the receptor in its active conformation.

Calcium cations bind to the first Calcium binding site in the inactive conformation. In the second binding site, Calcium cations are bound to both the active and inactive structures. In the third binding Site, the binding of the calcium facilitates the closure of lobe 1 and 2. This closure permits the interaction between the two lobes. The fourth binding site is located on lobe 2 in a place close to the CR domain. The agonist binding to the fourth binding site leads formation of homodimer interface bridge. This bridge between lobe 2 domain of subunit 1 and the CR domain of subunit 2, stabilize the open conformation.

The order of Calcium binding affinity to four of the bindings sites is as follows: 1 = 2 > 3 > 4. The lower affinity of Calcium to site 4 indicates that the receptor is activated only when the calcium concentration is elevated above the required concentration. That behavior makes the binding of calcium at site 4 to hold a major role in stabilization.

The CaSR also has binding sites for Magnesium and Gadolinium.

Anion Binding Sites edit

There are four anion binding sites in the ECD. Sites 1-3 are occupied in the inactive structure, whereas in the active structure only sites 2 and 4 are occupied.

Calcium-Sensing Receptor 7- Transmembrane Domain edit

Based on a similarity of CaSR to mGlu5, it is believed that in the inactivated form of the receptor, the VFT domain disrupts the interface between the 7TM domains, and the activation of the receptor force a reorientation of the 7TM domains.[14]

Signal transduction edit

The inactivated form of the receptor has an open conformation. upon binding of the fourth binding site, the structure of the receptor changes to a close conformation. The change in the structure conformation leads to inhibition of PTH release.

On the intracellular side, initiates the phospholipase C pathway,[15][16] presumably through a G type of G protein, which ultimately increases intracellular concentration of calcium, which inhibits vesicle fusion and exocytosis of parathyroid hormone. It also inhibits (not stimulates, as some[17] sources state) the cAMP dependent pathway.[16]

Ligands edit

Agonist edit

Positive allosteric modulators edit

Negative allosteric modulators edit

  • NPS 2143
  • Ronacaleret
  • Calhex 231

Antagonist edit

  • Calcilytics
  • Phosphate[20]

It is unknown whether Ca2+ alone can activate the receptor, but L-amino acids and g-Glutamyl peptides are shown to act as co-activator of the receptor. Those molecules intensify the intracellular responses evoked by Calcium cation.[21]

Pathology edit

Mutations that inactivate a CaSR gene cause familial hypocalciuric hypercalcemia (FHH) (also known as familial benign hypercalcemia because it is generally asymptomatic and does not require treatment),[22] when present in heterozygotes. Patients who are homozygous for CaSR inactivating mutations have more severe hypercalcemia.[23] Other mutations that activate CaSR are the cause of autosomal dominant hypocalcemia[24] or Type 5 Bartter syndrome. An alternatively spliced transcript variant encoding 1088 aa has been found for this gene, but its full-length nature has not been defined.[25]

Role in Chronic kidney disease edit

In CKD, the dysregulation of CaSR leads to a secondary hyperparathyroidism linked with osteoporosis, which considered as one of the main complications.

Patients suffers from secondary hyperparathyroidism require to make changes in their diet in order to balance the disease.[26] The diet recommendation includes restriction of Calcium, phosphate, and protein intake. Those nutrients are abundance in our diet and because of that, avoiding foods that contains those nutrients may limit our dietary options and can lead to other nutrients deficiencies.

Therapeutic application edit

The drugs cinacalcet and etelcalcetide are allosteric modifiers of the calcium-sensing receptor.[27] They are classified as a calcimimetics, binding to the calcium-sensing receptor and decreasing parathyroid hormone release.

Calcilytic drugs, which block CaSR, produce increased bone density in animal studies and have been researched for the treatment of osteoporosis. Unfortunately clinical trial results in humans have proved disappointing, with sustained changes in bone density not observed despite the drug being well tolerated.[28][29] More recent research has shown the CaSR receptor to be involved in numerous other conditions including Alzheimer's disease, asthma and some forms of cancer,[30][31][32][33] and calcilytic drugs are being researched as potential treatments for these. Recently it has been shown that biomimetic bone like apatite inhibits formation of bone through endochondral ossification pathway via hyperstimulation of extracellular calcium sensing receptor.[34]

Transactivation across the dimer can result in unique pharmacology for CaSR allosteric modulators. For example, Calhex 231, which shows a positive allosteric activity when bound to the allosteric site in just one protomer. In contrast, it shows a negative allosteric activity when occupying both the allosteric sites of the dimer.[18]

Interactions edit

Calcium-sensing receptor has been shown to interact with filamin.[35][36]

Role in sensory evaluation of food edit

Kokumi was discovered in Japan, 1989. It is defined as a sensation that enhances existing flavors and creates feelings of roundness, complexity, and richness in the mouth. The kokumi is present in different foods such as fish sauce, soybean, garlic, beans, etc.[37] The Kokumi substances are Gamma-glutamyl peptides.

CaSR is known to be expressed in the parathyroid gland and kidneys, but recent experiments showed that the receptor is also expressed in the alimentary canal (known as the digestive tract) and the near the taste buds on the back of the tongue.[38]

Gamma-glutamyl peptides are allosteric modulators of the CaSR, and the binding of those peptides to the CaSR on the tongue is what mediates the Kokumi sensation in the mouth.

In the mouth, unlike in other tissues, the influx of the extracellular Calcium does not affect the receptor activity. Instead, the activation of the CaSR is by the binding of the Gamma glutamine peptides.

Taste signal involves a release of intracellular calcium as respond to the molecule binding to the taste receptor, leads to secretion of neurotransmitter and taste perception. The simultaneous binding of gamma glutamine peptides to the CaSR increases the level of the intracellular calcium, and that intensify the taste perception.[38][39][37]

References edit

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Further reading edit

  • Hendy GN, D'Souza-Li L, Yang B, Canaff L, Cole DE (Oct 2000). "Mutations of the calcium-sensing receptor (CASR) in familial hypocalciuric hypercalcemia, neonatal severe hyperparathyroidism, and autosomal dominant hypocalcemia". Human Mutation. 16 (4): 281–96. doi:10.1002/1098-1004(200010)16:4<281::AID-HUMU1>3.0.CO;2-A. PMID 11013439. S2CID 31157004.
  • Fukumoto S (Mar 2002). "[Calcium-sensing receptor in bone cells]". Nihon Rinsho. Japanese Journal of Clinical Medicine. 60 (Suppl 3): 57–63. PMID 11979955.
  • Tfelt-Hansen J, Schwarz P, Brown EM, Chattopadhyay N (May 2003). "The calcium-sensing receptor in human disease". Frontiers in Bioscience. 8 (6): s377–90. doi:10.2741/1068. PMID 12700051.
  • Hu J, Spiegel AM (Aug 2003). "Naturally occurring mutations of the extracellular Ca2+-sensing receptor: implications for its structure and function". Trends in Endocrinology and Metabolism. 14 (6): 282–8. doi:10.1016/S1043-2760(03)00104-8. PMID 12890593. S2CID 28822680.
  • Aida K, Koishi S, Inoue M, Nakazato M, Tawata M, Onaya T (Sep 1995). "Familial hypocalciuric hypercalcemia associated with mutation in the human Ca(2+)-sensing receptor gene". The Journal of Clinical Endocrinology and Metabolism. 80 (9): 2594–8. doi:10.1210/jcem.80.9.7673400. PMID 7673400.
  • Aida K, Koishi S, Tawata M, Onaya T (Sep 1995). "Molecular cloning of a putative Ca(2+)-sensing receptor cDNA from human kidney". Biochemical and Biophysical Research Communications. 214 (2): 524–9. doi:10.1006/bbrc.1995.2318. PMID 7677761.
  • Chou YH, Pollak MR, Brandi ML, Toss G, Arnqvist H, Atkinson AB, Papapoulos SE, Marx S, Brown EM, Seidman JG (May 1995). "Mutations in the human Ca(2+)-sensing-receptor gene that cause familial hypocalciuric hypercalcemia". American Journal of Human Genetics. 56 (5): 1075–9. PMC 1801464. PMID 7726161.
  • Garrett JE, Capuano IV, Hammerland LG, Hung BC, Brown EM, Hebert SC, Nemeth EF, Fuller F (May 1995). "Molecular cloning and functional expression of human parathyroid calcium receptor cDNAs". The Journal of Biological Chemistry. 270 (21): 12919–25. doi:10.1074/jbc.270.21.12919. PMID 7759551.
  • Pollak MR, Brown EM, Estep HL, McLaine PN, Kifor O, Park J, Hebert SC, Seidman CE, Seidman JG (Nov 1994). "Autosomal dominant hypocalcaemia caused by a Ca(2+)-sensing receptor gene mutation". Nature Genetics. 8 (3): 303–7. doi:10.1038/ng1194-303. PMID 7874174. S2CID 22941518.
  • Pollak MR, Brown EM, Chou YH, Hebert SC, Marx SJ, Steinmann B, Levi T, Seidman CE, Seidman JG (Dec 1993). "Mutations in the human Ca(2+)-sensing receptor gene cause familial hypocalciuric hypercalcemia and neonatal severe hyperparathyroidism". Cell. 75 (7): 1297–303. doi:10.1016/0092-8674(93)90617-Y. PMID 7916660. S2CID 40886966.
  • Janicic N, Soliman E, Pausova Z, Seldin MF, Rivière M, Szpirer J, Szpirer C, Hendy GN (Nov 1995). "Mapping of the calcium-sensing receptor gene (CASR) to human chromosome 3q13.3-21 by fluorescence in situ hybridization, and localization to rat chromosome 11 and mouse chromosome 16". Mammalian Genome. 6 (11): 798–801. doi:10.1007/BF00539007. PMID 8597637. S2CID 19835161.
  • Bikle DD, Ratnam A, Mauro T, Harris J, Pillai S (Feb 1996). "Changes in calcium responsiveness and handling during keratinocyte differentiation. Potential role of the calcium receptor". The Journal of Clinical Investigation. 97 (4): 1085–93. doi:10.1172/JCI118501. PMC 507156. PMID 8613532.
  • Pearce SH, Trump D, Wooding C, Besser GM, Chew SL, Grant DB, Heath DA, Hughes IA, Paterson CR, Whyte MP (Dec 1995). "Calcium-sensing receptor mutations in familial benign hypercalcemia and neonatal hyperparathyroidism". The Journal of Clinical Investigation. 96 (6): 2683–92. doi:10.1172/JCI118335. PMC 185975. PMID 8675635.
  • Bai M, Quinn S, Trivedi S, Kifor O, Pearce SH, Pollak MR, Krapcho K, Hebert SC, Brown EM (Aug 1996). "Expression and characterization of inactivating and activating mutations in the human Ca2+o-sensing receptor". The Journal of Biological Chemistry. 271 (32): 19537–45. doi:10.1074/jbc.271.32.19537. PMID 8702647.
  • Baron J, Winer KK, Yanovski JA, Cunningham AW, Laue L, Zimmerman D, Cutler GB (May 1996). "Mutations in the Ca(2+)-sensing receptor gene cause autosomal dominant and sporadic hypoparathyroidism". Human Molecular Genetics. 5 (5): 601–6. doi:10.1093/hmg/5.5.601. PMID 8733126.
  • Freichel M, Zink-Lorenz A, Holloschi A, Hafner M, Flockerzi V, Raue F (Sep 1996). "Expression of a calcium-sensing receptor in a human medullary thyroid carcinoma cell line and its contribution to calcitonin secretion". Endocrinology. 137 (9): 3842–8. doi:10.1210/endo.137.9.8756555. PMID 8756555.
  • Chattopadhyay N, Ye C, Singh DP, Kifor O, Vassilev PM, Shinohara T, Chylack LT, Brown EM (Apr 1997). "Expression of extracellular calcium-sensing receptor by human lens epithelial cells". Biochemical and Biophysical Research Communications. 233 (3): 801–5. doi:10.1006/bbrc.1997.6553. PMID 9168937.
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External links edit

  • "Calcium-Sensing Receptors". IUPHAR Database of Receptors and Ion Channels. International Union of Basic and Clinical Pharmacology. Archived from the original on 2016-03-03. Retrieved 2007-10-25.
  • CASRdb - Calcium Sensing Receptor Database, McGill University
  • Receptors,+Calcium-Sensing at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • CASR+protein at the U.S. National Library of Medicine Medical Subject Headings (MeSH)

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