Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination

In studies of the transfer, distribution and biochemical activity of metal ions it is typically assumed that the phospholipid bilayer acts as an inert barrier. Yet, there is mounting evidence that metal ions can influence the physical properties of membranes. Little is known of the basis of this eff...

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Main Authors: Chanh Thi Minh Le, Aamd Houri, Nimalka Balage, Brian J. Smith, Adam Mechler
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-01-01
Series:Frontiers in Materials
Subjects:
Online Access:https://www.frontiersin.org/article/10.3389/fmats.2018.00080/full
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author Chanh Thi Minh Le
Aamd Houri
Nimalka Balage
Brian J. Smith
Adam Mechler
author_facet Chanh Thi Minh Le
Aamd Houri
Nimalka Balage
Brian J. Smith
Adam Mechler
author_sort Chanh Thi Minh Le
collection DOAJ
description In studies of the transfer, distribution and biochemical activity of metal ions it is typically assumed that the phospholipid bilayer acts as an inert barrier. Yet, there is mounting evidence that metal ions can influence the physical properties of membranes. Little is known of the basis of this effect. In this work the location and distribution of common metal ions: Na+, Mg2+, and Ca2+ in phospholipid membranes were studied. Computer simulations of lipid membrane segments in aqueous environment showed that the ions penetrate the membrane headgroup zone and co-localize with the phosphate and the ester moieties. Analysis of the chemical environment of the ions in the simulations suggested that the co-localization is facilitated by coordination to the polar oxygen atoms of the phosphate and ester groups in typical coordination geometries of each ionic species, where the coordination shells are completed by water molecules. In contrast, the counterions do not penetrate the headgroup zone but form a layer over the membrane instead; this layer is also an effective metal exclusion zone. Importantly, the choline groups appear to be distributed almost exactly in the same plane as the phosphate, suggesting that the zwitterion dipole is preferentially horizontally aligned: this suggests that the distribution of the Cl− over the membrane surface is not a direct result of interaction with the choline groups, but rather an effect of the field emanating from the metal ion content of the membrane. Such a well defined ion distribution is expected to have a strong influence on membrane properties, in particular phase transition temperatures via increased in-plane cohesion; this was proven by calorimetry measurements using differential scanning calorimetry of suspended liposomes and quartz crystal microbalance-based measurements on supported single bilayer membranes. These findings shed a new light on the role metal ions play in stabilizing biological membranes.
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spelling doaj.art-56e91f1315ba4840958d74cd75b2b7b82022-12-21T19:25:20ZengFrontiers Media S.A.Frontiers in Materials2296-80162019-01-01510.3389/fmats.2018.00080401354Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal CoordinationChanh Thi Minh LeAamd HouriNimalka BalageBrian J. SmithAdam MechlerIn studies of the transfer, distribution and biochemical activity of metal ions it is typically assumed that the phospholipid bilayer acts as an inert barrier. Yet, there is mounting evidence that metal ions can influence the physical properties of membranes. Little is known of the basis of this effect. In this work the location and distribution of common metal ions: Na+, Mg2+, and Ca2+ in phospholipid membranes were studied. Computer simulations of lipid membrane segments in aqueous environment showed that the ions penetrate the membrane headgroup zone and co-localize with the phosphate and the ester moieties. Analysis of the chemical environment of the ions in the simulations suggested that the co-localization is facilitated by coordination to the polar oxygen atoms of the phosphate and ester groups in typical coordination geometries of each ionic species, where the coordination shells are completed by water molecules. In contrast, the counterions do not penetrate the headgroup zone but form a layer over the membrane instead; this layer is also an effective metal exclusion zone. Importantly, the choline groups appear to be distributed almost exactly in the same plane as the phosphate, suggesting that the zwitterion dipole is preferentially horizontally aligned: this suggests that the distribution of the Cl− over the membrane surface is not a direct result of interaction with the choline groups, but rather an effect of the field emanating from the metal ion content of the membrane. Such a well defined ion distribution is expected to have a strong influence on membrane properties, in particular phase transition temperatures via increased in-plane cohesion; this was proven by calorimetry measurements using differential scanning calorimetry of suspended liposomes and quartz crystal microbalance-based measurements on supported single bilayer membranes. These findings shed a new light on the role metal ions play in stabilizing biological membranes.https://www.frontiersin.org/article/10.3389/fmats.2018.00080/fullphospholipidbilayer membraneionic environmentmetal coordinationphase transitioncomputer simulations
spellingShingle Chanh Thi Minh Le
Aamd Houri
Nimalka Balage
Brian J. Smith
Adam Mechler
Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
Frontiers in Materials
phospholipid
bilayer membrane
ionic environment
metal coordination
phase transition
computer simulations
title Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
title_full Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
title_fullStr Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
title_full_unstemmed Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
title_short Interaction of Small Ionic Species With Phospholipid Membranes: The Role of Metal Coordination
title_sort interaction of small ionic species with phospholipid membranes the role of metal coordination
topic phospholipid
bilayer membrane
ionic environment
metal coordination
phase transition
computer simulations
url https://www.frontiersin.org/article/10.3389/fmats.2018.00080/full
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AT nimalkabalage interactionofsmallionicspecieswithphospholipidmembranestheroleofmetalcoordination
AT brianjsmith interactionofsmallionicspecieswithphospholipidmembranestheroleofmetalcoordination
AT adammechler interactionofsmallionicspecieswithphospholipidmembranestheroleofmetalcoordination