M. Taglialatela

Exchange of conduction pathways between two related K+ channels

The structure of the ion conduction pathway or pore of voltage-gated ion channels is unknown, although the linker between the membrane spanning segments S5 and S6 has been suggested to form part of the pore in potassium channels. To test whether this region controls potassium channel conduction, a 21-amino acid segment of the S5-S6 linker was transplanted from the voltage-activated potassium channel NGK2 to another potassium channel DRK1, which has very different pore properties. In the resulting chimeric channel, the single channel conductance and blockade by external and internal tetraethylammonium (TEA) ion were characteristic of the donor NGK2 channel. Thus, this 21-amino acid segment controls the essential biophysical properties of the pore and may form the conduction pathway of these potassium channels.

Novel voltage clamp to record small, fast currents from ion channels expressed in Xenopus oocytes.

The present report describes a novel technique for voltage-clamping amphibian oocytes in which part of the membrane is isolated by a vaseline gap and the cytoplasmic fluid is exchanged by cutting or permeabilizing the remaining membrane. The main features of this open-oocyte, vaseline-gap voltage clamp are: (a) low current noise (1 nA at 3 kHz), (b) control of the ionic composition of both the internal and external media, (c) fast time resolution (20-100 microseconds time constant of decay of the capacity transient) and (d) stable recordings for several hours. These features allow reliable measurements of tail or gating currents and the new method is especially suitable when either of these currents must be measured to test the effects of mutations introduced into the cDNAs of cloned ion channels.

Inactivation determined by a single site in K+ pores

An N-terminus peptide or a C-terminus mechanism involving a single residue in transmembrane segment 6 produces inactivation in voltage-dependent K+ channels. Here we show that a single position in the pore of K+ channels can produce inactivation having characteristics distinct from either N- or C-type inactivation. In a chimeric K+ channel (CHM), the point reversion CHM V 369I produced fast inactivation and CHM V 369S had the additional effect of halving K+ conductance consistent with a position in the pore. The result was not restricted to CHM; mutating position 369 in the naturally occurring channel Kv2.1 also produced fast inactivation. Like N- and C-types of inactivation, pore or P-type inactivation was characterized by short bursts terminated by rapid entry into the inactivated state. Unlike C-type inactivation, in which external tetraethylammonium (TEA) produced a simple blockade that slowed inactivation and reduced currents, in P-type inactivation external TEA increased currents. Unlike N-type inactivation, internal TEA produced a simple reduction in current and K+ occupancy of the pore had no effect. External TEA was not the only cation to increase current; external K+ enhanced channel availability and recovery from inactivation. Additional features of P-type inactivation were residue-specific effects on the extent of inactivation and removal of inactivation by a point reversion at position 374, which also regulates conductance. The demonstration of P-type inactivation indicates that pore residues in K+ channels may be part of the inactivation gating machinery.

Differences between the deep pores of K+ channels determined by an interacting pair of nonpolar amino acids

The pore of a chimeric K+ channel, CHM, differed from its parental host channel, Kv2.1, by 9 amino acids. Four were located in a putative deep region and 5 in a nearby outer mouth. Point reversions were without restorative effects, and reversions V369I or L374V in the deep pore produced novel phenotypes. Among double mutations, only V369I and L374V were effective in restoring the Kv2.1 pore phenotype. Adding a change in charge at Q382K in the outer pore fully restored the parental phenotype. Thus, the pore appears to have an inner, deep region where ions such as K+ and TEA+ may be regulated by nonpolar residues and an outer region where ions may be regulated by charged residues.

A single nonpolar residue in the deep pore of related K+ channels acts as a K+:Rb+ conductance switch.

K+ and Rb+ conductances (GK+ and GRb+) were investigated in two delayed rectifier K+ channels (Kv2.1 and Kv3.1) cloned from rat brain and a chimera (CHM) of the two channels formed by replacing the putative pore region of Kv2.1 with that of Kv3.1. CHM displayed ion conduction properties which resembled Kv3.1. In CHM, GK+ was three times greater than that of Kv2.1 and GRb+/GK+ = 0.3 (compared with 1.5 and 0.7, respectively, in Kv2.1 and Kv3.1). A point mutation in CHM L374V, which restored 374 to its Kv2.1 identity, switched the K+/Rb+ conductance profiles so that GK+ was reduced fourfold, GRb+ was increased twofold, and GRb+/GK+ = 2.8. Quantitative restoration of the Kv2.1 K+/Rb+ profiles, however, required simultaneous point mutations at three nonadjacent residues suggesting the possibility of interactions between residues within the pore. The importance of leucine at position 374 was verified when reciprocal changes in K+/Rb+ conductances were produced by the mutation of V374L in Kv2.1 (GK+ was increased threefold, GRb+ was decreased threefold, and GRb+/GK+ = 0.2). We conclude that position 374 is responsible for differences in GK+ and GRb+ between Kv2.1 and Kv3.1 and, given its location near residues critical for block by internal tetraethylammonium, may be part of a cation binding site deep within the pore.

Regulation of K+/Rb+ selectivity and internal TEA blockade by mutations at a single site in K+ pores

A conservative reversion at position 374 in a chimeric K+ pore, CHM, switched the preferred ionic conductance from K+ to Rb+. To understand how selectivity was switched, codons for 18 different amino acids were substituted at position 374 in each of two different K+ channels CHM and Kv2.1, the host channel for CHM. After injection of cRNA into Xenopus oocytes, less than half of the substituted mutants expressed functional channels. In both CHM and Kv2.1, channels with the substituted hydrophobic residues Val or Ile expressed Rb+-preferring pores while channels with the substituted polar residues Thr or Ser expressed K+-preferring pores. Val or Ile stabilized while Thr or Ser destabilized blockade by internal tetraethylammonium (TEA) confirming the importance of hydrophobic interactions for blockade. TEA blockade was dependent upon the charge carrier and was more effective in the presence of the ion having the larger conductance. The results are consistent with a model in which the side chains at position 374 form a filter for K+ and Rb+ ions and a site for blockade by internal TEA.

Cloned Human Inward Rectifier K+ Channel as a Target for Class III Methanesulfonanilides

Methanesulfonanilide derivatives such as dofetilide are members of the widely used Class III group of cardiac antiarrhythmic drugs. A methanesulfonanilide-sensitive cardiac current has been identified as IKr, the rapidly activating component of the repolarizing outward cardiac K+ current, IK. IKr may be encoded by the human ether-related gene (hERG), which belongs to the family of voltage-dependent K+ (Kv) channels having six putative transmembrane segments. The hERG also expresses an inwardly rectifying, methanesulfonanilide-sensitive K+ current. Here we show that hIRK, a member of the two-transmembrane-segment family of inward K+ rectifiers that we have cloned from human heart, is a target for dofetilide. hIRK currents, expressed heterologously in Xenopus oocytes, are blocked by dofetilide at submicromolar concentrations (IC50 = 533 nmol/L at 40 mV and 20 degrees C). The drug has no significant blocking effect on the human cardiac Kv channels hKv1.2, hKv1.4, hKv1.5, or hKv2.1. The block is voltage dependent, use dependent, and shortens open times in a manner consistent with open-channel block. While steady state block is strongest at depolarized potentials, recovery from block is very slow even at hyperpolarized potentials (tau = 1.17 seconds at -80 mV). Thus, block of hIRK may persist during diastole and might thereby affect cardiac excitability.

Gating currents from a delayed rectifier K+ channel with altered pore structure and function.

For voltage-sensitive ion channels, charged elementswithin the membrane electric field are thought togeneratedisplacementorgatingcurrents(1). Topographxadical models (2-4)have assigned thecharged elements orvoltage sensor to a fourth transmembrane a-helix(S4)and the models have received supportfrom mutagenesisexperiments (5-6). The pore has been assigned to adifferent region, and in K+ channels, this appears to bethe highly-conserved S5-S6 linker (7-9). To test thehypothesis that the pore and the voltage sensor arestructurally distinct, we compared ion conduction andgating currents arising from two delayed rectifier K+channels, DRKI (10) and a chimera DRK/NGKL374V(11, 12), whose sequences even though identical in S4,the putative voltage sensor differed at eight of the 21residues in the S5-S6linker(6) as shown in the followingalignment.parent in single-channel recordingsfrom cell-attachedpatches of oocytes expressing currents from the twospecies of cRNA. The single channel conductance forK+ was -8and 4 pS for DRKI and DRK/NGKL374V,respectively (Fig. 1, B, D). Single-channelkinetics alsoshowed large differences: the long openings typical ofDRKI were converted into short openings in DRKINGK L374V (Fig. 1C). Furthermore, in DRKI cellxadattached patcheswith Iso-Rb+in the pipette, the inwardRb+ conductance and theoutward K+ conductancewereidentical (gRb+IgK+ was -1;Fig. 1D, left), whereasDRK/NGKL374V showed a strong inward rectification(Fig. 1, D, right), and the gRb+IgK+ ratio rose to 2.4. Inaddition, the profile for blockade by external and interxadnal tetraethylammonium ions differed markedly bexadtween the two channels (7,11,13).DRKI 357:

Rescue of lethal subunits into functional K+ channels

In a chimeric, voltage-dependent K+ channel (CHM), the valine at position 369 and the leucine at position 374 interact within the pore or P-region to regulate ion permeation and block. Here we show that the point mutation, CHM V369L, abolished channel function whereas previous experiments showed that CHM V369 and CHM V369I are functional. Coinjection of lethal CHM V369L cRNA with CHM L374V cRNA but not CHM cRNA generated functional heteromultimers. The whole-cell Rb+/K+ conductance ratio was 2.98 +/- 0.43 for CHM L374V and was reduced to 0.87 +/- 0.04 for the coexpressed CHM V369L and CHM L374V subunits. When single-channel currents were recorded, a single class of CHM V369L/CHM L374V heteromultimers was identified. This class was readily distinguishable from CHM L374V homomultimers by K+ conductance, gating, and blockade by internal tetraethylammonium. Coinjection experiments at various RNA ratios suggest that the CHM V369L/CHM L374V heteromultime, assuming it to be a tetramer, was composed of three CHM L374V subunits and one CHM V369L subunit. It appears that in the critical P-region of CHM position 369 may tolerate only one leucine.