Abstract
The Na+/H+ exchanger of the plasma membrane of S. pombe (SpNHE1) removes intracellular sodium in exchange for an extracellular proton. We examined the structure and functional role of amino acids 360–393 of putative transmembrane (TM) segment XI of SpNHE1. Structural analysis suggested that it had a helical propensity over amino acids 360–368, an extended region from 369–378 and was helical over amino acids 379–386. TM XI was sensitive to side chain alterations. Mutation of eight amino acids to alanine resulted in loss of one or both of LiCl or NaCl tolerance when re-introduced into SpNHE1 deficient S. pombe. Mutation of seven other amino acids had minor effects. Analysis of structure and functional mutations suggested that Glu361 may be involved in cation coordination on the cytoplasmic face of the protein with a negative charge in this position being important. His367, Ile371 and Gly372 were important in function. Ile371 may have important hydrophobic interactions with other residues and Gly372 may be important in maintaining an extended conformation. Several residues from Val377 to Leu384 are important in function possibly involved in hydrophobic interactions with other amino acids. We suggest that TM XI forms part of the ion translocation core of this Na+/H+ exchanger.
Highlights
In yeast, plasma membrane Na+/H+ antiporters serve to mediate salt tolerance by removal of intracellular sodium in exchange for extracellular protons
Our results are the first examination of the structure and function of this region of the membrane protein. They support the hypothesis that SpNHE1 has a “Na+/H+ exchanger”-like fold within the protein and that amino acids 360–393 are a critical part of this fold
We examined amino acids of the putative TM segment XI of SpNHE1, which we hypothesized is important in activity S. pombe
Summary
Plasma membrane Na+/H+ antiporters serve to mediate salt tolerance by removal of intracellular sodium in exchange for extracellular protons. In the well studied Na+/H+ exchangers, one key feature that has been noted is the critical nature of transmembrane (TM) segments IV and XI. These two segments create a characteristic fold. Both are discontinuous helices and at their crossing point are unfolded, accommodating charged and polar residues that neutralize the dipoles of the helices within the lipid bilayer This region may harbor the ion translocation center[11,14]. Our results are the first examination of the structure and function of this region of the membrane protein They support the hypothesis that SpNHE1 has a “Na+/H+ exchanger”-like fold within the protein and that amino acids 360–393 are a critical part of this fold
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