Several mechanisms have been proposed to explain how ion channels and transporters distinguish between similar ions, a process crucial for maintaining proper cell function. Of these, three can be broadly classed as mechanisms involving specific positional constraints on the ion coordinating ligands which arise through: a ‘‘rigid cavity’’, a ‘strained cavity ’ and ‘reduced ligand fluctuations’. Each operates in subtly different ways yet can produce markedly different influences on ion selectivity. Here we expand upon preliminary investigations into the reduced ligand fluctuation mechanism of ion selectivity by simulating how a series of model systems respond to a decrease in ligand thermal fluctuations while simultaneously maintaining optima...
<p><b>, for (A) 5-fold, (B) 6-fold, (C) 7-fold and (D) 8-fold coordination states.</b> These are com...
Ion channels form pores across the lipid bilayer, selectively allowing inorganic ions to cross the m...
AbstractPotassium channels are exquisitely selective, allowing K+ to pass across cell membranes whil...
<div><p>Several mechanisms have been proposed to explain how ion channels and transporters distingui...
AbstractThe ability to discriminate between different cations efficiently is essential for the prope...
AbstractThe ability of macrocycles, enzymes, ion channels, transporters, and DNA to differentiate am...
The ability of macrocycles, enzymes, ion channels, transporters, and DNA to differentiate among ion ...
Some biological molecules can distinguish between ions of similar nature, which may be achieved by e...
AbstractTo provide utility in understanding the molecular evolution of ion-selective biomembrane cha...
<p>Selectivity arises from the difference in the entropy change from unconstrained ligands () to con...
How K(+) channels are able to conduct certain cations yet not others remains an important but unreso...
<p><b>for (A) 4 fold, (B) 5 fold, (C) 6 fold and (D) 7 fold coordination states.</b> These are compa...
The ability of biological ion channels to conduct selected ions across cell membranes is critical fo...
AbstractK+ ions seemingly permeate K-channels rapidly because channel binding sites mimic coordinati...
AbstractHow K+ channels are able to conduct certain cations yet not others remains an important but ...
<p><b>, for (A) 5-fold, (B) 6-fold, (C) 7-fold and (D) 8-fold coordination states.</b> These are com...
Ion channels form pores across the lipid bilayer, selectively allowing inorganic ions to cross the m...
AbstractPotassium channels are exquisitely selective, allowing K+ to pass across cell membranes whil...
<div><p>Several mechanisms have been proposed to explain how ion channels and transporters distingui...
AbstractThe ability to discriminate between different cations efficiently is essential for the prope...
AbstractThe ability of macrocycles, enzymes, ion channels, transporters, and DNA to differentiate am...
The ability of macrocycles, enzymes, ion channels, transporters, and DNA to differentiate among ion ...
Some biological molecules can distinguish between ions of similar nature, which may be achieved by e...
AbstractTo provide utility in understanding the molecular evolution of ion-selective biomembrane cha...
<p>Selectivity arises from the difference in the entropy change from unconstrained ligands () to con...
How K(+) channels are able to conduct certain cations yet not others remains an important but unreso...
<p><b>for (A) 4 fold, (B) 5 fold, (C) 6 fold and (D) 7 fold coordination states.</b> These are compa...
The ability of biological ion channels to conduct selected ions across cell membranes is critical fo...
AbstractK+ ions seemingly permeate K-channels rapidly because channel binding sites mimic coordinati...
AbstractHow K+ channels are able to conduct certain cations yet not others remains an important but ...
<p><b>, for (A) 5-fold, (B) 6-fold, (C) 7-fold and (D) 8-fold coordination states.</b> These are com...
Ion channels form pores across the lipid bilayer, selectively allowing inorganic ions to cross the m...
AbstractPotassium channels are exquisitely selective, allowing K+ to pass across cell membranes whil...