Interaction of N-terminal peptide analogues of the Na+,K+-ATPase with membranes
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Open Access
Type
ArticleAuthor/s
Nguyen, KhoaGarcia, Alvaro
Sani, Marc-Antoine
Diaz, Dil
Dubey, Vikas
Clayton, Daniel
Dal Poggetto, Giovanni
Cornelius, Flemming
Payne, Richard J.
Separovic, Frances
Khandelia, Himanshu
Clarke, Ronald J.
Abstract
The Na+,K+-ATPase, which is present in the plasma membrane of all animal cells, plays a crucial role in maintaining the Na+ and K+ electrochemical potential gradients across the membrane. Recent studies have suggested that the N-terminus of the protein’s catalytic α-subunit is ...
See moreThe Na+,K+-ATPase, which is present in the plasma membrane of all animal cells, plays a crucial role in maintaining the Na+ and K+ electrochemical potential gradients across the membrane. Recent studies have suggested that the N-terminus of the protein’s catalytic α-subunit is involved in an electrostatic interaction with the surrounding membrane, which controls the protein’s conformational equilibrium. However, because the N-terminus could not yet be resolved in any X-ray crystal structures, little information about this interaction is so far available. In measurements utilising poly-L-lysine as a model of the protein’s lysine-rich N-terminus and using lipid vesicles of defined composition, here we have identified the most likely origin of the interaction as one between positively charged lysine residues of the N-terminus and negatively charged headgroups of phospholipids (notably phosphatidylserine) in the surrounding membrane. Furthermore, to isolate which segments of the N-terminus could be involved in membrane binding, we chemically synthesized N-terminal fragments of various lengths. Based on a combination of results from RH421 UV/visible absorbance measurements and solid-state 31P and 2H NMR using these N-terminal fragments as well as MD simulations it appears that the membrane interaction arises from lysine residues prior to the conserved LKKE motif of the N-terminus. The MD simulations indicate that the strength of the interaction varies significantly between different enzyme conformations.
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See moreThe Na+,K+-ATPase, which is present in the plasma membrane of all animal cells, plays a crucial role in maintaining the Na+ and K+ electrochemical potential gradients across the membrane. Recent studies have suggested that the N-terminus of the protein’s catalytic α-subunit is involved in an electrostatic interaction with the surrounding membrane, which controls the protein’s conformational equilibrium. However, because the N-terminus could not yet be resolved in any X-ray crystal structures, little information about this interaction is so far available. In measurements utilising poly-L-lysine as a model of the protein’s lysine-rich N-terminus and using lipid vesicles of defined composition, here we have identified the most likely origin of the interaction as one between positively charged lysine residues of the N-terminus and negatively charged headgroups of phospholipids (notably phosphatidylserine) in the surrounding membrane. Furthermore, to isolate which segments of the N-terminus could be involved in membrane binding, we chemically synthesized N-terminal fragments of various lengths. Based on a combination of results from RH421 UV/visible absorbance measurements and solid-state 31P and 2H NMR using these N-terminal fragments as well as MD simulations it appears that the membrane interaction arises from lysine residues prior to the conserved LKKE motif of the N-terminus. The MD simulations indicate that the strength of the interaction varies significantly between different enzyme conformations.
See less
Date
2018-03-06Publisher
ElsevierLicence
© 2018. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/Citation
Nguyen, K., Garcia, A., Sani, M.-A., Diaz, D., Dubey, V., Clayton, D., … Clarke, R. J. (2018). Interaction of N-terminal peptide analogues of the Na+,K+-ATPase with membranes. Biochimica et Biophysica Acta (BBA) - Biomembranes, 1860(6), 1282–1291. https://doi.org/10.1016/j.bbamem.2018.03.002Share