CFTR

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The Cystic Fibrosis Transmembrane Regulator protein (CFTR) regulates ion concentration in extracellular fluid due to its role as a plasma membrane Cl<sup>-</sup> channel on the lumenal (apical) membrane in [[Epithelial cells|epithelial cells]]&nbsp;<ref>Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science</ref>.&nbsp; It is a member of the ABC superfamily of proteins and is the only Cl- channel (passive transporter) in this family (the others are active transporters). It has got 12 transmembrane domains, with two nucleotide binding domains (NBD1 and NBD2) and a regulatory domain. The binding of ATP is essential for the function for the channel, NBD1 and NBD2 both bind ATP however only NBD2 can hydrolyse ATP.&nbsp;CFTR&nbsp;shares homolgy with&nbsp;P-glycoprotein, apart from the fact that CFTR contains a large regulatory domain (R domain).<br>
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The Cystic Fibrosis Transmembrane Regulator protein (CFTR) regulates ion concentration in extracellular fluid due to its role as a plasma membrane Cl<sup>-</sup> channel on the lumenal (apical) membrane in [[Epithelial cells|epithelial cells]]&nbsp;<ref>Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science</ref>.&nbsp; It is a member of the ABC superfamily of proteins and is the only Cl<sup>- </sup>channel (passive transporter) in this family (the others are active transporters). It has got 12 transmembrane domains, with two nucleotide binding domains (NBD1 and NBD2) and a regulatory domain. The binding of ATP is essential for the function for the channel, NBD1 and NBD2 both bind ATP however only NBD2 can hydrolyse ATP.&nbsp;CFTR&nbsp;shares homolgy with&nbsp;P-glycoprotein, apart from the fact that CFTR contains a large regulatory domain (R domain).<br>  
  
 
The CFTR gene was cloned in 1989, and,&nbsp;when mutated, can cause [[Cystic fibrosis|cystic fibrosis]].&nbsp;The mutation is [[Recessive gene|recessive]]&nbsp;and therefore requires homozygous mutant alleles for the phenotype to manifest. So far, over 1600 mutations of the [[CFTR|CFTR]] gene have been discovered, with&nbsp;the most common being the ∆F508 mutation, however some mutations have been identified as being unique to an individual. Some of the other more common mutations include; G542X G551D N1303K and W1282X.  
 
The CFTR gene was cloned in 1989, and,&nbsp;when mutated, can cause [[Cystic fibrosis|cystic fibrosis]].&nbsp;The mutation is [[Recessive gene|recessive]]&nbsp;and therefore requires homozygous mutant alleles for the phenotype to manifest. So far, over 1600 mutations of the [[CFTR|CFTR]] gene have been discovered, with&nbsp;the most common being the ∆F508 mutation, however some mutations have been identified as being unique to an individual. Some of the other more common mutations include; G542X G551D N1303K and W1282X.  
  
In the ∆F508 mutation a [[Phenylalanine|phenylalanine]] residue at amino acid 508 has been deleted, leaving&nbsp;a sequence of only 1479 amino acids (formerly 1480).&nbsp;This mutation is a class II mutation where abnormal processing occurs in the endoplasmic reticulum.&nbsp;This abnormal processing&nbsp;means that the Nucleotide Binding Domain 1 (NBD1) cannot bind ATP. Subsequent signalling from ATP binding to open/close the Cl- channel&nbsp;does not occur and&nbsp;the cell renders the channel non-functional <ref>Patrick AE and Thomas PJ (2012) Development of CFTR structure. Front. Pharmacol. 3:162. doi: 10.3389/fphar.2012.00162</ref>. The protein is then degraded via [[Ubiquitin|ubiquitin tagging]].&nbsp;&nbsp;<ref>Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science</ref>. The lack of Cl<sup>-</sup> channel means than Cl<sup>-</sup> cannot be transported out of the apical membrane into the lumen, so it remains both in the cell and on both sides of the basolateral membrane.  
+
In the ∆F508 mutation a [[Phenylalanine|phenylalanine]] residue at amino acid 508 has been deleted, leaving&nbsp;a sequence of only 1479 amino acids (formerly 1480).&nbsp;This mutation is a class II mutation where abnormal processing occurs in the endoplasmic reticulum.&nbsp;This abnormal processing&nbsp;means that the Nucleotide Binding Domain 1 (NBD1) cannot bind ATP correctly. Subsequent signalling from ATP binding to open/close the Cl- channel&nbsp;does not occur and&nbsp;the cell renders the channel non-functional <ref>Patrick AE and Thomas PJ (2012) Development of CFTR structure. Front. Pharmacol. 3:162. doi: 10.3389/fphar.2012.00162</ref>. The protein is then degraded via [[Ubiquitin|ubiquitin tagging]].&nbsp;&nbsp;<ref>Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science</ref>. The lack of Cl<sup>-</sup> channel means than Cl<sup>-</sup> cannot be transported out of the apical membrane into the lumen. Once Cl<sup>- </sup>accumulate in the cell, they remain&nbsp;both in the cell and on both sides of the basolateral membrane (the paracellular movement of Na<sup>+ </sup>is also decreased.  
  
[[Cystic fibrosis|Cystic Fibrosis]]&nbsp;is a disease condition caused by&nbsp;several mutations&nbsp;in the [[Gene|gene]] encoding CFTR protein, which functions as a Cl<sup>-</sup> channel in the [[Plasma membrane|plasma membrane]] of epithelial cells. The CFTR&nbsp;channel plays a particularly important role especially in the [[Lungs|lungs]] - where it controls certain ion concentrations found in the extracellular fluid&nbsp;<ref>Alberts &amp;amp;amp;lt;i&amp;amp;amp;gt;et al.&amp;amp;amp;lt;/i&amp;amp;amp;gt; (2008) Molecular Biology of the Cell 5th ed. p.666. Garland Science</ref>. The disease causes decreased chloride concentration in the airway which leads to the thickening of the gel layer. As it thickens it becomes too heavy for the cilia to brush it along and so sticks to the cilia. Many organs become affected by [[Cystic fibrosis|Cystic Fibrosis]], which disrupts their normal functioning. A major problem is encountered in the [[Lung|lungs]], where there is clogging of the [[Bronchial passage|bronchial passage]] and infection. The repeated inflammation to combat infection damages lung tissue,&nbsp;so breathing is impeded and [[Lung|lungs]] are slowly destroyed. In [[Liver|liver]], disease affects digestion, as it plugs in the small [[Bile duct|bile ducts]]. In the pancreas, a precipitate forms on&nbsp;ducts&nbsp;to the bowel, meaning that digestive enzymes cannot&nbsp;be transported and digestion is insufficiently processed.&nbsp;Other o[[Organ|rgans]] which are altered by the disease are the&nbsp;[[Small intestine|small intestine]] and the [[Reproductive duct|reproductive duct]].<br>
+
[[Cystic fibrosis|Cystic Fibrosis]]&nbsp;is a disease condition caused by&nbsp;several mutations&nbsp;in the [[Gene|gene]] encoding CFTR protein, which normally functions as a Cl<sup>-</sup> channel in the [[Plasma membrane|plasma membrane]] of epithelial cells. The CFTR&nbsp;channel plays a particularly important role, especially in the [[Lungs|lungs]] - where it controls certain ion concentrations found in the extracellular fluid&nbsp;<ref>Alberts &amp;amp;amp;amp;lt;i&amp;amp;amp;amp;gt;et al.&amp;amp;amp;amp;lt;/i&amp;amp;amp;amp;gt; (2008) Molecular Biology of the Cell 5th ed. p.666. Garland Science</ref>. The disease causes decreased chloride concentration in the airway which leads to the thickening of the gel layer. As it thickens it becomes too heavy for the cilia to brush it along and so sticks to the cilia. Many organs become affected by [[Cystic fibrosis|Cystic Fibrosis]], which disrupts their normal functioning. A major problem is encountered in the [[Lung|lungs]], where there is clogging of the [[Bronchial passage|bronchial passage]] and infection. The repeated inflammation to combat infection damages lung tissue,&nbsp;so breathing is impeded and [[Lung|lungs]] are slowly destroyed. In the&nbsp;[[Liver|liver]], disease affects digestion, as it plugs in the small [[Bile duct|bile ducts]]. In the pancreas, a precipitate forms in&nbsp;ducts&nbsp;to the bowel, meaning that digestive enzymes cannot&nbsp;be transported and digestion is insufficiently processed, leading to malnourishment.&nbsp;Other o[[Organ|rgans]] which are altered by the disease are the&nbsp;[[Small intestine|small intestine]] and the [[Reproductive duct|reproductive duct]].<br>  
  
 
=== References  ===
 
=== References  ===
  
 
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Revision as of 17:12, 16 October 2012

The Cystic Fibrosis Transmembrane Regulator protein (CFTR) regulates ion concentration in extracellular fluid due to its role as a plasma membrane Cl- channel on the lumenal (apical) membrane in epithelial cells [1].  It is a member of the ABC superfamily of proteins and is the only Cl- channel (passive transporter) in this family (the others are active transporters). It has got 12 transmembrane domains, with two nucleotide binding domains (NBD1 and NBD2) and a regulatory domain. The binding of ATP is essential for the function for the channel, NBD1 and NBD2 both bind ATP however only NBD2 can hydrolyse ATP. CFTR shares homolgy with P-glycoprotein, apart from the fact that CFTR contains a large regulatory domain (R domain).

The CFTR gene was cloned in 1989, and, when mutated, can cause cystic fibrosis. The mutation is recessive and therefore requires homozygous mutant alleles for the phenotype to manifest. So far, over 1600 mutations of the CFTR gene have been discovered, with the most common being the ∆F508 mutation, however some mutations have been identified as being unique to an individual. Some of the other more common mutations include; G542X G551D N1303K and W1282X.

In the ∆F508 mutation a phenylalanine residue at amino acid 508 has been deleted, leaving a sequence of only 1479 amino acids (formerly 1480). This mutation is a class II mutation where abnormal processing occurs in the endoplasmic reticulum. This abnormal processing means that the Nucleotide Binding Domain 1 (NBD1) cannot bind ATP correctly. Subsequent signalling from ATP binding to open/close the Cl- channel does not occur and the cell renders the channel non-functional [2]. The protein is then degraded via ubiquitin tagging.  [3]. The lack of Cl- channel means than Cl- cannot be transported out of the apical membrane into the lumen. Once Cl- accumulate in the cell, they remain both in the cell and on both sides of the basolateral membrane (the paracellular movement of Na+ is also decreased.

Cystic Fibrosis is a disease condition caused by several mutations in the gene encoding CFTR protein, which normally functions as a Cl- channel in the plasma membrane of epithelial cells. The CFTR channel plays a particularly important role, especially in the lungs - where it controls certain ion concentrations found in the extracellular fluid [4]. The disease causes decreased chloride concentration in the airway which leads to the thickening of the gel layer. As it thickens it becomes too heavy for the cilia to brush it along and so sticks to the cilia. Many organs become affected by Cystic Fibrosis, which disrupts their normal functioning. A major problem is encountered in the lungs, where there is clogging of the bronchial passage and infection. The repeated inflammation to combat infection damages lung tissue, so breathing is impeded and lungs are slowly destroyed. In the liver, disease affects digestion, as it plugs in the small bile ducts. In the pancreas, a precipitate forms in ducts to the bowel, meaning that digestive enzymes cannot be transported and digestion is insufficiently processed, leading to malnourishment. Other organs which are altered by the disease are the small intestine and the reproductive duct.

References

  1. Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science
  2. Patrick AE and Thomas PJ (2012) Development of CFTR structure. Front. Pharmacol. 3:162. doi: 10.3389/fphar.2012.00162
  3. Alberts, Bruce (2002), Molecular Biology Of The Cell, 4th edition, Garland Science
  4. Alberts &amp;amp;amp;lt;i&amp;amp;amp;gt;et al.&amp;amp;amp;lt;/i&amp;amp;amp;gt; (2008) Molecular Biology of the Cell 5th ed. p.666. Garland Science
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