Determinants of the proton selectivity of the colicin A channel.

The channel formed by colicin A in planar lipid bilayers has an outsized selectivity for protons compared to any other ion, even though it allows large ions, such as tetraethylammonium, to permeate readily. A mechanism to account for this discrepancy remains obscure. We considered that protons may traverse a separate pathway but were unable to find any evidence for one. Manipulations that interfere with ionic conduction, such as replacing some of the water in the pore with a nonelectrolyte, reduce the proton current along with the ionic current. Lipids have been proposed to play a structural role in the channel, but we found that the proton selectivity was unaffected by various gross changes in the lipid composition of the bilayer, effectively ruling out any specific effect of lipids in the selectivity and offering no support for their role in structure. The 10-helix channel-forming domains of colicins Ia and E1 are structurally homologous to that of colicin A but do not select so remarkably for protons; thus we were able to use them to probe for the regions responsible for the high selectivity. Using hybrids made by helix swapping among these proteins, we found that the anomalous selectivity could be localized to the five C-terminal helices of colicin A.

Anomalous proton selectivity in a large channel: colicin A.

Some of the bactericidal proteins known as colicins exert their toxic action by forming a large, nonselective channel in the inner membrane of target bacteria. The structure of this channel is unknown. It conducts large ions but has a much smaller conductance than would be expected for a channel of its deduced size. Here we report that the colicin channel, particularly the colicin A channel, is selective for protons over other cations (and anions) by many orders of magnitude. This was deduced from measurements of reversal potentials in pH gradients across planar lipid bilayers containing these channels. For example, in symmetric 0.1 M KCl with a pH 5/pH 8 gradient across the membrane, the reversal potential of colicin A is -21 mV, rather than 0. Such a result would be unremarkable for a narrow channel but is beyond explanation by current understanding of permeation for a channel of its diameter. For this reason, we re-examined the issue of the diameter of the channel lumen and confirmed that the lumen is indeed "too large" ( approximately 10 A) to select for protons by the amount that we measure. We are thus compelled to propose that an unorthodox mechanism is at work in this protein.

Translocation of a functional protein by a voltage-dependent ion channel.

The voltage-dependent gating of the colicin channel involves a substantial structural rearrangement that results in the transfer of about 35% of the 200 residues in its pore-forming domain across the membrane. This transfer appears to represent an unusual type of protein translocation that does not depend on a large, multimeric, protein pore. To investigate the ability of this system to transport arbitrary proteins, we made use of a pair of strongly interacting proteins, either of which could serve as a translocated cargo or as a probe to detect the other. Here we show that both an 86-residue and a 134-residue hydrophilic protein inserted into the translocated segment of colicin A are themselves translocated and are functional on the trans side of the bilayer. The disparate features of these proteins suggest that the colicin channel has a general protein translocation mechanism.