FXYD domain-containing ion transport regulator 5 also named dysadherin (human) or RIC (mouse) is a
protein that in humans is encoded by the FXYD5gene.[5]
Function
This gene encodes a member of a family of small membrane proteins that share a 35-amino acid signature sequence domain, beginning with the sequence PFXYD and containing 7 invariant and 6 highly conserved amino acids. The approved human gene nomenclature for the family is FXYD-domain containing ion transport regulator. Mouse FXYD5 has been termed RIC (Related to Ion Channel). FXYD2, also known as the gamma subunit of the
Na,K-ATPase, regulates the properties of that enzyme.
FXYD1 (phospholemman),
FXYD2 (gamma),
FXYD3 (MAT-8),
FXYD4 (CHIF), and FXYD5 (RIC) have been shown to induce channel activity in experimental expression systems. Transmembrane topology has been established for two family members (FXYD1 and FXYD2), with the N-terminus extracellular and the
C-terminus on the cytoplasmic side of the membrane. This gene product, FXYD5, has not been characterized as a protein. Two transcript variants have been found for this gene, and they are both predicted to encode the same protein.[5]
Dysadherin is the gamma5 subunit of the human
Na,K-ATPase. Of all the FXYD members, dysadherin is the only member that has a large extracellular sequence of 140 amino acids. Dysadherin has been observed to be over-expressed on the surface of cells that have down regulated levels of surface
E-cadherin.
CCL2 (bone homing cytokine)is a protein that is highly affected by silencing dysadherin expression. Dysadherin interferes with cell adhesion via beta1 subunit interactions.[6] Dysadherin is a target for an extracellular antibody drug conjugate where the antibody to dysadherin is attached to a cardiac glycoside.[7]
Clinical significance
Dysadherin has been found to be a marker for metastatic cancers and found up-regulated in multiple cancer types.[7]
Sweadner KJ, Rael E (August 2000). "The FXYD gene family of small ion transport regulators or channels: cDNA sequence, protein signature sequence, and expression". Genomics. 68 (1): 41–56.
doi:
10.1006/geno.2000.6274.
PMID10950925.
Omasa T, Chen YG, Mantalaris A, Wu JH (January 2001). "A cDNA from human bone marrow encoding a protein exhibiting homology to the ATP1gamma1/PLM/MAT8 family of transmembrane proteins". Biochimica et Biophysica Acta (BBA) - Gene Structure and Expression. 1517 (2): 307–10.
doi:
10.1016/S0167-4781(00)00251-7.
PMID11342114.
Sato H, Ino Y, Miura A, Abe Y, Sakai H, Ito K, Hirohashi S (September 2003). "Dysadherin: expression and clinical significance in thyroid carcinoma". The Journal of Clinical Endocrinology and Metabolism. 88 (9): 4407–12.
doi:
10.1210/jc.2002-021757.
PMID12970317.
Shimada Y, Yamasaki S, Hashimoto Y, Ito T, Kawamura J, Soma T, Ino Y, Nakanishi Y, Sakamoto M, Hirohashi S, Imamura M (April 2004). "Clinical significance of dysadherin expression in gastric cancer patients". Clinical Cancer Research. 10 (8): 2818–23.
doi:
10.1158/1078-0432.CCR-0633-03.
PMID15102690.
S2CID6282644.
Shimada Y, Hashimoto Y, Kan T, Kawamura J, Okumura T, Soma T, Kondo K, Teratani N, Watanabe G, Ino Y, Sakamoto M, Hirohashi S, Imamura M (2004). "Prognostic significance of dysadherin expression in esophageal squamous cell carcinoma". Oncology. 67 (1): 73–80.
doi:
10.1159/000080289.
PMID15459499.
S2CID34215274.
Batistatou A, Makrydimas G, Zagorianakou N, Zagorianakou P, Nakanishi Y, Agnantis NJ, Hirohashi S, Charalabopoulos K (2007). "Expression of dysadherin and E-cadherin in trophoblastic tissue in normal and abnormal pregnancies". Placenta. 28 (5–6): 590–2.
doi:
10.1016/j.placenta.2006.09.004.
PMID17084448.
FXYD domain-containing ion transport regulator 5 also named dysadherin (human) or RIC (mouse) is a
protein that in humans is encoded by the FXYD5gene.[5]
Function
This gene encodes a member of a family of small membrane proteins that share a 35-amino acid signature sequence domain, beginning with the sequence PFXYD and containing 7 invariant and 6 highly conserved amino acids. The approved human gene nomenclature for the family is FXYD-domain containing ion transport regulator. Mouse FXYD5 has been termed RIC (Related to Ion Channel). FXYD2, also known as the gamma subunit of the
Na,K-ATPase, regulates the properties of that enzyme.
FXYD1 (phospholemman),
FXYD2 (gamma),
FXYD3 (MAT-8),
FXYD4 (CHIF), and FXYD5 (RIC) have been shown to induce channel activity in experimental expression systems. Transmembrane topology has been established for two family members (FXYD1 and FXYD2), with the N-terminus extracellular and the
C-terminus on the cytoplasmic side of the membrane. This gene product, FXYD5, has not been characterized as a protein. Two transcript variants have been found for this gene, and they are both predicted to encode the same protein.[5]
Dysadherin is the gamma5 subunit of the human
Na,K-ATPase. Of all the FXYD members, dysadherin is the only member that has a large extracellular sequence of 140 amino acids. Dysadherin has been observed to be over-expressed on the surface of cells that have down regulated levels of surface
E-cadherin.
CCL2 (bone homing cytokine)is a protein that is highly affected by silencing dysadherin expression. Dysadherin interferes with cell adhesion via beta1 subunit interactions.[6] Dysadherin is a target for an extracellular antibody drug conjugate where the antibody to dysadherin is attached to a cardiac glycoside.[7]
Clinical significance
Dysadherin has been found to be a marker for metastatic cancers and found up-regulated in multiple cancer types.[7]
Sweadner KJ, Rael E (August 2000). "The FXYD gene family of small ion transport regulators or channels: cDNA sequence, protein signature sequence, and expression". Genomics. 68 (1): 41–56.
doi:
10.1006/geno.2000.6274.
PMID10950925.
Omasa T, Chen YG, Mantalaris A, Wu JH (January 2001). "A cDNA from human bone marrow encoding a protein exhibiting homology to the ATP1gamma1/PLM/MAT8 family of transmembrane proteins". Biochimica et Biophysica Acta (BBA) - Gene Structure and Expression. 1517 (2): 307–10.
doi:
10.1016/S0167-4781(00)00251-7.
PMID11342114.
Sato H, Ino Y, Miura A, Abe Y, Sakai H, Ito K, Hirohashi S (September 2003). "Dysadherin: expression and clinical significance in thyroid carcinoma". The Journal of Clinical Endocrinology and Metabolism. 88 (9): 4407–12.
doi:
10.1210/jc.2002-021757.
PMID12970317.
Shimada Y, Yamasaki S, Hashimoto Y, Ito T, Kawamura J, Soma T, Ino Y, Nakanishi Y, Sakamoto M, Hirohashi S, Imamura M (April 2004). "Clinical significance of dysadherin expression in gastric cancer patients". Clinical Cancer Research. 10 (8): 2818–23.
doi:
10.1158/1078-0432.CCR-0633-03.
PMID15102690.
S2CID6282644.
Shimada Y, Hashimoto Y, Kan T, Kawamura J, Okumura T, Soma T, Kondo K, Teratani N, Watanabe G, Ino Y, Sakamoto M, Hirohashi S, Imamura M (2004). "Prognostic significance of dysadherin expression in esophageal squamous cell carcinoma". Oncology. 67 (1): 73–80.
doi:
10.1159/000080289.
PMID15459499.
S2CID34215274.
Batistatou A, Makrydimas G, Zagorianakou N, Zagorianakou P, Nakanishi Y, Agnantis NJ, Hirohashi S, Charalabopoulos K (2007). "Expression of dysadherin and E-cadherin in trophoblastic tissue in normal and abnormal pregnancies". Placenta. 28 (5–6): 590–2.
doi:
10.1016/j.placenta.2006.09.004.
PMID17084448.