Sodium-chloride symporter

SLC12A3
Identifiers
AliasesSLC12A3, NCC, NCCT, TSC, solute carrier family 12 member 3, Sodium-chloride symporter
External IDsOMIM: 600968 MGI: 108114 HomoloGene: 287 GeneCards: SLC12A3
Gene location (Human)
Chr.Chromosome 16 (human)[1]
BandNo data availableStart56,865,207 bp[1]
End56,915,850 bp[1]
Orthologs
SpeciesHumanMouse
Entrez

6559

20497

Ensembl

ENSG00000070915

ENSMUSG00000031766

UniProt

P55017

P59158

RefSeq (mRNA)

NM_000339
NM_001126107
NM_001126108

NM_001205311
NM_019415

RefSeq (protein)

NP_000330
NP_001119579
NP_001119580

NP_001192240
NP_062288

Location (UCSC)Chr 16: 56.87 – 56.92 MbChr 16: 94.33 – 94.37 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

The sodium-chloride symporter (also known as Na+-Cl cotransporter, abbreviated as NCC or NCCT, or as the thiazide-sensitive Na+-Cl cotransporter or TSC for short) is a cotransporter in the kidney which has the function of reabsorbing sodium and chloride ions from the tubular fluid into the cells of the distal convoluted tubule of the nephron. It is a member of the SLC12 cotransporter family of electroneutral cation-coupled chloride cotransporters. In humans, it is encoded by the gene SLC12A3 (solute carrier family 12 member 3) located in 16q13.[5]

Molecular biology

The sodium-chloride symporter or NCC is a member of the SLC12 cotransporter family of electroneutral cation-coupled chloride cotransporter, along with the potassium-chloride cotransporters (K+-Cl cotransporters or KCCs), the sodium-potassium-chloride cotransporters (Na+-K+-Cl cotransporters or NKCCs) and orphan member CIP (cotransporter interacting protein) and CCC9. The sodium-chloride symporter's protein sequence has a high degree of identity between different mammalian species (over 90% between human, rat and mouse). The SLC12A3 gene encodes for a protein of 1,002 to 1,030 amino acid residues. NCC is a transmembrane protein, presumed to have a hydrophobic core of either 10 or 12 transmembrane domains with intracellular amino- and carboxyl-terminus domains. The exact structure of the NCC protein is unknown, as it has not yet been crystallized. The NCC protein forms homodimers at the plasma membrane.

N-glycosylation occurs in two sites in a long extracellular loop connecting two transmembrane domains within the hydrophobic core. This posttranslational modification is necessary for proper folding and transport of the protein to the plasma membrane.[6]

Function

Because NCC is located at the apical membrane of the distal convoluted tubule of the nephron, it faces the lumen of the tubule and is in contact with the tubular fluid. Using the sodium gradient across the apical membrane of the cells in distal convoluted tubule, the sodium-chloride symporter transports Na+ and Cl from the tubular fluid into these cells. Afterward, the Na+ is pumped out of the cell and into the bloodstream by the Na+-K+ ATPase located at the basal membrane and the Cl leaves the cells through the basolateral chloride channel ClC-Kb. The sodium-chloride symporter accounts for the absorption of 5% of the salt filtered at the glomerulus. NCC activity is known to have two control mechanisms affecting protein trafficking to the plasma membrane and transporter kinetics by phosphorylation and de-phosphorylation of conserved serine/threonine residues.

As NCC has to be at the plasma membrane to function, its activity can be regulated by increasing or decreasing the amount of protein at the plasma membrane. Some NCC modulators, such as the WNK3 and WNK4 kinases may regulate the amount of NCC at the cell surface by inducing the insertion or removal, respectively, of the protein from the plasma membrane.[7][8]

Furthermore, many residues of NCC can be phosphorylated or dephosphorylated to activate or inhibit NCC uptake of Na+ and Cl. Other NCC modulators, including intracellular chloride depletion, angiotensin II, aldosterone and vasopressin, can regulate NCC activity by phosphorylating conserved serine/threonine residues.[9][10][11] NCC activity can be inhibited by thiazides, which is why this symporter is also known as the thiazide-sensitive Na+-Cl cotransporter.[5]

Pathology

Gitelman's syndrome

A loss of NCC function is associated with Gitelman syndrome, an autosomic recessive disease characterized by salt wasting and low blood pressure, hypokalemic metabolic alkalosis, hypomagnesemia and hypocalciuria.[12]

Over a hundred different mutations in the NCC gene have been described as causing Gitelman syndrome, including nonsense, frameshift, splice site and missense mutations. Two different types of mutations exist within the group of missense mutations causing loss of NCC function. Type I mutations cause a complete loss of NCC function, in which the synthesized protein is not properly glycosylated. NCC protein harboring type I mutations is retained in the endoplasmic reticulum and cannot be trafficked to the cell surface.[13] Type II mutations cause a partial loss of NCC function in which the cotransporter is trafficked to the cell surface but has an impaired insertion in the plasma membrane. NCC harboring type II mutations have normal kinetic properties but are present in lower amounts at the cell surface, resulting in a decreased uptake of sodium and chloride.[14] NCC harboring type II mutations is still under control of its modulators and can still increase or decrease its activity in response to stimuli, whereas type I mutations cause a complete loss of function and regulation of the cotransporter.[15] However, in some patients with Gitelman's syndrome, no mutations in the NCC gene have been found despite extensive genetic work-up.

Hypertension and blood pressure

NCC has also been implicated to play a role in control of blood pressure in the open population, with both common polymorphisms and rare mutations altering NCC function, renal salt reabsorption and, presumably, blood pressure. Individuals with rare mutations in genes responsible for salt control in the kidney, including NCC, have been found to have a lower blood pressure than controls.[16] NCC harboring these mutations has a lower function than wild-type cotransporter although some mutations found in individuals in the open population seem to be less deleterious to cotransporter function than mutations in individuals with Gitelman's syndrome.[15]

Furthermore, heterozygous carriers of mutations causing Gitelman syndrome (i.e. individuals who have a mutation in one of the two alleles and do not have the disease) have a lower blood pressure than non-carriers in the same family.[17]

Pseudohypoaldosteronism type II

Type II pseudohypoaldosteronism (PHA2), also known as Gordon's syndrome, is an autosomal dominant disease in which there is an increase in NCC activity leading to short stature, increased blood pressure, increased serum K+ levels, increased urinary calcium excretion and hyperchloremic metabolic acidosis. However, PHA2 is not caused by mutations within the NCC gene, but by mutations in NCC regulators WNK1 and WNK4. Patients respond well to treatment with thiazide-type diuretics.

See also

References

  1. 1 2 3 GRCh38: Ensembl release 89: ENSG00000070915 - Ensembl, May 2017
  2. 1 2 3 GRCm38: Ensembl release 89: ENSMUSG00000031766 - Ensembl, May 2017
  3. "Human PubMed Reference:".
  4. "Mouse PubMed Reference:".
  5. 1 2 Mastroianni N, De Fusco M, Zollo M, Arrigo G, Zuffardi O, Bettinelli A, Ballabio A, Casari G (August 1996). "Molecular cloning, expression pattern, and chromosomal localization of the human Na-Cl thiazide-sensitive cotransporter (SLC12A3)". Genomics. 35 (3): 486–93. PMID 8812482. doi:10.1006/geno.1996.0388.
  6. Gamba G (May 2009). "The thiazide-sensitive Na+-Cl cotransporter: molecular biology, functional properties, and regulation by WNKs.". American Journal of Physiology Renal Physiology. 297 (4): F838–48. PMC 3350128Freely accessible. PMID 19474192. doi:10.1152/ajprenal.00159.2009.
  7. Rinehart J, Kahle K, de los Heros P, Vazquez N, Meade P, Wilson F, Hebert S, Gimenez I, Gamba G, Lifton R (November 2005). "WNK3 kinase is a positive regulator of NKCC2 and NCC, renal cation-Cl cotransporters required for normal blood pressure homeostasis". PNAS. 102 (46): 16777–16782. PMC 1283841Freely accessible. PMID 16275913. doi:10.1073/pnas.0508303102.
  8. Zhou B, Zhuang J, Gu D, Wang H, Cebotaru L, Guggino W, Cai H (January 2010). "WNK4 Enhances the Degradation of NCC through a Sortilin-Mediated Lysosomal Pathway". Journal of the American Society of Nephrology. 21 (1): 82–92. PMC 2799281Freely accessible. PMID 19875813. doi:10.1681/ASN.2008121275.
  9. Pacheco-Alvarez D, San Cristóbal P, Meade P, Moreno E, Vazquez N, Muñoz E, Díaz A, Juárez ME, Giménez I, Gamba G (August 2006). "The Na+:Cl Cotransporter Is Activated and Phosphorylated at the Amino-terminal Domain upon Intracellular Chloride Depletion". J. Biol. Chem. 281 (39): 28755–28763. PMID 16887815. doi:10.1074/jbc.M603773200.
  10. van der Lubbe N, Lim C, Fenton R, Meima M, Jan Danser A, Zietse R, Hoorn E (August 2010). "Angiotensin II induces phosphorylation of the thiazide-sensitive sodium chloride cotransporter independent of aldosterone". Kidney International. 79 (1): 66–76. PMID 20720527. doi:10.1038/ki.2010.290.
  11. Pedersen NB, Hofmeister MV, Rosenbaek LL, Nielsen J, Fenton RA (July 2010). "Vasopressin induces phosphorylation of the thiazide-sensitive sodium chloride cotransporter in the distal convoluted tubule". Kidney International. 78 (2): 160–169. PMID 20445498. doi:10.1038/ki.2010.130.
  12. Knoers NV, Levtchenko EN (2008). "Gitelman syndrome". Orphanet J Rare Dis. 3: 22. PMC 2518128Freely accessible. PMID 18667063. doi:10.1186/1750-1172-3-22.
  13. de Jong JC; can der Vliet WA; van den Heuvel LPWJ; Willems PHGM; Knoers NVAM; Bindels RJM (2002). "Functional Expression of Mutations in the Human NaCl Cotransporter: Evidence for Impaired Routing Mechanisms in Gitelman's Syndrome". JASN. 13 (6): 1442–1448. PMID 12039972. doi:10.1097/01.ASN.0000017904.77985.03.
  14. Sabath E, Meade P, Berkman J, de los Heros P, Moreno E, Bobadilla NA, Vázquez N, Ellison DH, Gamba G (2004). "Pathophysiology of functional mutations of the thiazide-sensitive Na-Cl cotransporter in Gitelman disease". Am J Physiol Renal Physiol. 287 (2): F195–F203. PMID 15068971. doi:10.1152/ajprenal.00044.2004.
  15. 1 2 Acuña R, Martínez de la Maza L, Ponce-Coria J, Vázquez N, Ortal-Vite P, Pacheco-Alvarez D, Bobadilla NA, Gamba G (2009). "Rare mutations in SLC12A1 and SLC12A3 protect against hypertension by reducing the activity of renal salt cotransporters". J Hypertension. 29 (3): 475–83. PMID 21157372. doi:10.1097/HJH.0b013e328341d0fd.
  16. Weizhen Ji; Jia Nee Foo; Brian J O'Roak; Hongyu Zhao; Martin G Larson; David B Simon; Christopher Newton-Cheh; Matthew W State; Daniel Levy; Richard P Lifton (2008). "Rare independent mutations in renal salt handling genes contribute to blood pressure variation". Nature Genetics. 40 (5): 592–599. PMC 3766631Freely accessible. PMID 18391953. doi:10.1038/ng.118.
  17. Fava C, Montagnana M, Rosberg L, Burri P, Almgren P, Jönsson A, Wanby P, Lippi G, Minuz P, Hulthèn G, Aurell M, Melander O (2008). "Subjects heterozygous for genetic loss of function of the thiazide-sensitive cotransporter have reduced blood pressure". Hum. Mol. Genet. 17 (3): 413–18. PMID 17981812. doi:10.1093/hmg/ddm318.

Further reading

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