Phylogeny of anion exchangers: Could trout AE1 conductive properties be shared by other members of the gene family?

A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an...

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Published inBiochimica et biophysica acta Vol. 1726; no. 3; pp. 244 - 250
Main Authors Guizouarn, Hélène, Christen, Richard, Borgese, Franck
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 30.11.2005
Subjects
Animals
Anion channel
Anion Exchange Protein 1, Erythrocyte - classification
Anion Exchange Protein 1, Erythrocyte - genetics
Anion Exchange Protein 1, Erythrocyte - metabolism
Anion exchanger
Band3
Biological Transport
Cells, Cultured
Chlorides - metabolism
Electric Conductivity
Erythrocyte
Fish Proteins - classification
Fish Proteins - genetics
Fish Proteins - metabolism
Oocytes - physiology
Phylogeny
Skates (Fish) - genetics
Taurine
Taurine - metabolism
Trout - genetics
Xenopus laevis
Zebrafish Proteins - classification
Zebrafish Proteins - genetics
Zebrafish Proteins - metabolism
Erythrocyte
Anion exchanger
Band3
Taurine
Anion channel
Phylogeny
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Abstract A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an electroneutral Cl −/HCO 3 − exchange through the plasma membrane; however, trout AE1 (tAE1) is able to spontaneously form an anion conductive pathway permeable to some inorganic cations (Na + and K +) as well as to organic osmolytes such as taurine. Therefore, it has been proposed that this major erythrocyte membrane protein could play a key role for the cell volume regulation of trout red cells. By analogy, it was envisioned that other fish anion exchangers could play a similar role in osmolyte loss induced by erythrocyte swelling. We have cloned AE1 from Raja erinacea and Danio rerio and studied their properties after expression in Xenopus laevis oocytes. In this study, we show that none of them is able to induce any conductive pathway or taurine permeability in Xenopus oocytes. Our phylogenetic analyses show that, first, all present AE1 genes have a common ancestor distinct from that of AE2 and AE3 and second, tAE1 is a true AE1 ortholog. The question of whether tAE1 conductive properties are a derived character in the trout lineage within Euteleostei or whether other AE1 members can share these properties is then discussed.
AbstractList A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an electroneutral Cl −/HCO 3 − exchange through the plasma membrane; however, trout AE1 (tAE1) is able to spontaneously form an anion conductive pathway permeable to some inorganic cations (Na + and K +) as well as to organic osmolytes such as taurine. Therefore, it has been proposed that this major erythrocyte membrane protein could play a key role for the cell volume regulation of trout red cells. By analogy, it was envisioned that other fish anion exchangers could play a similar role in osmolyte loss induced by erythrocyte swelling. We have cloned AE1 from Raja erinacea and Danio rerio and studied their properties after expression in Xenopus laevis oocytes. In this study, we show that none of them is able to induce any conductive pathway or taurine permeability in Xenopus oocytes. Our phylogenetic analyses show that, first, all present AE1 genes have a common ancestor distinct from that of AE2 and AE3 and second, tAE1 is a true AE1 ortholog. The question of whether tAE1 conductive properties are a derived character in the trout lineage within Euteleostei or whether other AE1 members can share these properties is then discussed.
A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an electroneutral Cl-/HCO3- exchange through the plasma membrane; however, trout AE1 (tAE1) is able to spontaneously form an anion conductive pathway permeable to some inorganic cations (Na+ and K+) as well as to organic osmolytes such as taurine. Therefore, it has been proposed that this major erythrocyte membrane protein could play a key role for the cell volume regulation of trout red cells. By analogy, it was envisioned that other fish anion exchangers could play a similar role in osmolyte loss induced by erythrocyte swelling. We have cloned AE1 from Raja erinacea and Danio rerio and studied their properties after expression in Xenopus laevis oocytes. In this study, we show that none of them is able to induce any conductive pathway or taurine permeability in Xenopus oocytes. Our phylogenetic analyses show that, first, all present AE1 genes have a common ancestor distinct from that of AE2 and AE3 and second, tAE1 is a true AE1 ortholog. The question of whether tAE1 conductive properties are a derived character in the trout lineage within Euteleostei or whether other AE1 members can share these properties is then discussed.A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an electroneutral Cl-/HCO3- exchange through the plasma membrane; however, trout AE1 (tAE1) is able to spontaneously form an anion conductive pathway permeable to some inorganic cations (Na+ and K+) as well as to organic osmolytes such as taurine. Therefore, it has been proposed that this major erythrocyte membrane protein could play a key role for the cell volume regulation of trout red cells. By analogy, it was envisioned that other fish anion exchangers could play a similar role in osmolyte loss induced by erythrocyte swelling. We have cloned AE1 from Raja erinacea and Danio rerio and studied their properties after expression in Xenopus laevis oocytes. In this study, we show that none of them is able to induce any conductive pathway or taurine permeability in Xenopus oocytes. Our phylogenetic analyses show that, first, all present AE1 genes have a common ancestor distinct from that of AE2 and AE3 and second, tAE1 is a true AE1 ortholog. The question of whether tAE1 conductive properties are a derived character in the trout lineage within Euteleostei or whether other AE1 members can share these properties is then discussed.
A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose. Indeed, the different known AE1 from mammals or fish do not exhibit the same transport features: all studied anion exchangers 1 (AE1) catalyse an electroneutral Cl-/HCO3- exchange through the plasma membrane; however, trout AE1 (tAE1) is able to spontaneously form an anion conductive pathway permeable to some inorganic cations (Na+ and K+) as well as to organic osmolytes such as taurine. Therefore, it has been proposed that this major erythrocyte membrane protein could play a key role for the cell volume regulation of trout red cells. By analogy, it was envisioned that other fish anion exchangers could play a similar role in osmolyte loss induced by erythrocyte swelling. We have cloned AE1 from Raja erinacea and Danio rerio and studied their properties after expression in Xenopus laevis oocytes. In this study, we show that none of them is able to induce any conductive pathway or taurine permeability in Xenopus oocytes. Our phylogenetic analyses show that, first, all present AE1 genes have a common ancestor distinct from that of AE2 and AE3 and second, tAE1 is a true AE1 ortholog. The question of whether tAE1 conductive properties are a derived character in the trout lineage within Euteleostei or whether other AE1 members can share these properties is then discussed.
Author Christen, Richard
Borgese, Franck
Guizouarn, Hélène
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Keywords Erythrocyte
Anion exchanger
Band3
Taurine
Anion channel
Phylogeny
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Snippet A phylogenetic tree of anion exchangers (AE) was performed in order to better understand relationships between the different known AE and how they arose....
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SubjectTerms Animals
Anion channel
Anion Exchange Protein 1, Erythrocyte - classification
Anion Exchange Protein 1, Erythrocyte - genetics
Anion Exchange Protein 1, Erythrocyte - metabolism
Anion exchanger
Band3
Biological Transport
Cells, Cultured
Chlorides - metabolism
Electric Conductivity
Erythrocyte
Fish Proteins - classification
Fish Proteins - genetics
Fish Proteins - metabolism
Oocytes - physiology
Phylogeny
Skates (Fish) - genetics
Taurine
Taurine - metabolism
Trout - genetics
Xenopus laevis
Zebrafish Proteins - classification
Zebrafish Proteins - genetics
Zebrafish Proteins - metabolism
Title Phylogeny of anion exchangers: Could trout AE1 conductive properties be shared by other members of the gene family?
URI https://dx.doi.org/10.1016/j.bbagen.2005.07.010
https://www.ncbi.nlm.nih.gov/pubmed/16150548
https://www.proquest.com/docview/68830033
Volume 1726
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