Research Article

Crystal Structure of the Human K2P TRAAK, a Lipid- and Mechano-Sensitive K+ Ion Channel

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Science  27 Jan 2012:
Vol. 335, Issue 6067, pp. 436-441
DOI: 10.1126/science.1213808


TRAAK channels, members of the two–pore domain K+ (potassium ion) channel family K2P, are expressed almost exclusively in the nervous system and control the resting membrane potential. Their gating is sensitive to polyunsaturated fatty acids, mechanical deformation of the membrane, and temperature changes. Physiologically, these channels appear to control the noxious input threshold for temperature and pressure sensitivity in dorsal root ganglia neurons. We present the crystal structure of human TRAAK at a resolution of 3.8 angstroms. The channel comprises two protomers, each containing two distinct pore domains, which create a two-fold symmetric K+ channel. The extracellular surface features a helical cap, 35 angstroms tall, that creates a bifurcated pore entryway and accounts for the insensitivity of two–pore domain K+ channels to inhibitory toxins. Two diagonally opposed gate-forming inner helices form membrane-interacting structures that may underlie this channel’s sensitivity to chemical and mechanical properties of the cell membrane.

Cellular electrical signaling relies on a resting potential difference that originates in the membrane’s permeability to K+ (1). Termed “potassium leakage” by Hodgkin and Huxley (2), cellular leak currents are approximated by the behavior of constitutively open K+-selective pores but deviate in detail, suggesting more complex underlying channel behavior. Leak K+ currents are now recognized as resulting from the activity of two–pore domain K+ ion channels (K2P channels) (3). Discovered as the final member of the K+ channel family (46), K2P channels have remained less well characterized than other K+ channels. Perhaps the prospect of studying simple “leakage” has somewhat delayed progress.

The view of K2P channels as passive K+ leaks has recently changed. K2P channels control the resting potential in many cells, and their regulation can directly tune cellular excitability. K2P channels have among the most varied sets of ion channel modulators, including mechanical force, temperature, lipid interaction, voltage, pH, posttranslational modification, and accessory protein interaction (3, 7, 8). Pharmacologically, K2P channels are targets of antidepressants, inhalational anesthetics, neuroprotective agents, and respiratory stimulants (912). Their deregulation underlies human pathophysiologies including Birk-Barel syndrome and familial migraine with aura (13, 14).

K2P channels constitute one of five clades within the K+ channel superfamily (fig. S1, A and B). Although their sequences are diverse (figs. S1C and S2), K2P channels have two shared characteristics. First, K2P channels contain two concatenated pore domains on a single protein chain protomer (fig. S1A); each pore domain contains an outer and inner membrane-spanning helix flanking a membrane-reentrant segment that forms a pore helix and K+ selectivity filter. K+ channels of known structure have one pore domain per protomer and form four-fold symmetric tetramers. Second, K2P channels contain a segment of ~60 amino acids on the extracellular side of the first pore domain. This segment has often been referred to as a “loop,” and its role in channel function has been unknown.

The best-studied subfamily of K2P channels includes TRAAK (TWIK-related arachidonic acid–stimulated K+ channel), TREK-1, and TREK-2 (fig. S3) (1517). Unlike other K2P channels, they are mechanosensitive and modulated by polyunsaturated fatty acids and temperature (1821). Physiologically, TRAAK and TREK-1 appear to regulate the noxious input threshold for temperature and pressure sensitivity in mouse dorsal root ganglia (22). These channels are highly sensitive to the structure and chemical composition of the lipid bilayer, but a mechanistic rationale for these biophysical properties has not been possible in the absence of structural information.

Crystal structure of TRAAK. Human TRAAK was recombinantly expressed and purified from Pichia pastoris. Diffracting crystals were obtained by mutating two consensus N-linked glycosylation sites (Asn104 → Gln, Asn108 → Gln), and the predicted intrinsically unstructured C-terminal region was truncated (to Gln300). Four complementary approaches were taken to assess the functional integrity of this modified construct. First, macroscopic currents were examined in cells expressing TRAAK (Fig. 1A). Channels displayed approximate time and voltage independence of activation. Current-voltage relationships did not indicate strong rectification. Expressed channels were K+-selective, as demonstrated by the change in reversal potential as a function of external K+ concentration [K+] (Fig. 1A, inset). Second, channel activation by arachidonic acid and mechanical force was examined. TRAAK channels were robustly activated above basal levels after perfusion of arachidonic acid (Fig. 1B). The extent of activation above basal levels by arachidonic acid was comparable to that measured from full-length TRAAK channels (Fig. 1C). Application of positive pressure through the pipette to outside-out patches also activated TRAAK channels (fig. S4). [Future quantitative assessments of the gating response to mechanical perturbation will require simultaneous measurements of pressure and membrane curvature to ascertain tension as the independent variable (23).] Third, purified TRAAK was reconstituted into lipid vesicles and examined in a K+ flux assay. A decrease in fluorescence indicative of K+ flux was observed from TRAAK-reconstituted, but not empty, vesicles loaded with high [K+] into buffer without K+ (Fig. 1D). Fourth, recordings were made with planar lipid bilayers into which purified TRAAK channels were reconstituted (Fig. 1E). The bilayer recordings show voltage-independent channels exhibiting exquisite selectivity for K+ over Na+ (Fig. 1F). Taken together, these data show that the channel we have expressed, purified, and crystallized exhibits the fundamental biophysical properties of previously described TRAAK channels (24).

Fig. 1

Analysis of TRAAK channel activity. (A) Macroscopic currents from Chinese hamster ovary (CHO) cells expressing the crystal construct of TRAAK. Current was measured in whole-cell mode during a voltage ramp from –100 mV to 40 mV from a holding potential of –80 mV in 800 ms. Curves recorded from cells in 5, 70, and 150 mM external [K+] are displayed. The inset is a plot of reversal potential determined from voltage ramps recorded from cells in 5, 15, 70, and 150 mM external [K+]. (B) Arachidonic acid activation of the crystal construct of the TRAAK channel. (C) Arachidonic acid activation of the full-length channel. Current-voltage relationship is plotted from whole-cell recordings during voltage pulses from –100 to 40 mV from a holding potential of –80 mV before and after perfusion of arachidonic acid (+AA). (D) K+ flux assay in which K+ efflux drives the carbonyl cyanide m-chlorophenyl hydrazone (CCCP)–mediated uptake of protons, which are detected by fluorophore 9-amino-6-chloro-2-methoxyacridine (ACMA). Vesicles were loaded with 150 mM K+, 0 mM Na+, and assayed in buffer with 0 mM K+, 150 mM Na+. Relative fluorescence change recorded from TRAAK-reconstituted (red) and empty (black) lipid vesicles is shown. Addition of the K+ ionophore valinomycin results in flux from crystal construct TRAAK-reconstituted and empty vesicles. (E) Current recorded from TRAAK reconstituted into planar lipid bilayers under bi-ionic conditions. Current was recorded during voltage pulses from –120 to 120 mV from a holding potential of 0 mV with internal 150 mM K+, 0 mM Na+ and external 0 mM K+, 150 mM Na+ by electrophysiological convention. Zero current level is indicated by a dashed red line. (F) Current-voltage relationship plotted from data in (E).

Crystals of TRAAK grown in 150 mM KCl diffracted to 3.8 Å. Initial attempts at molecular replacement using known K+ channel structures were unsuccessful. The structure was thus solved with phases determined from a multiple-wavelength isomorphous replacement with anomalous scattering experiment using a crystal grown in the presence of TlNO3 substituted for KCl. Additional register information was obtained from anomalous scattering data collected from crystals derivatized with CH3Hg+ to covalently label cysteine residues. The experimentally phased maps were of sufficient quality to model the majority of the structure (fig. S5), and the final TRAAK model was refined to Rwork/Rfree = 31.7/32.3% with good geometry (table S1).

TRAAK crystallized in space group p212121 with two protomers, each containing two nonidentical pore domains—pore domain 1 and pore domain 2—in the asymmetric unit, forming a single K+ channel with a molecular two-fold axis (along the K+ conduction pathway) noncoincident with crystal symmetry axes (fig. S6). Viewed from the bilayer plane, the transmembrane region of the channel spans ~35 Å in height and is formed by the outer helix, pore helix, K+ selectivity filter, and inner helix from the four pore domains (Fig. 2A). Extensions of the inner helices and the linker between pore domains 1 and 2 protrude ~10 Å further into the cytoplasmic side. On the extracellular side of the transmembrane region is a structural unit we term the helical cap, extending ~35 Å above the membrane. The helical cap is not observed in other ion channels of known structure. When viewed from the cytoplasmic side of the membrane, the channel is rhomboid-shaped; the inner helices of pore domain 1 are separated by ~75 Å across a long axis, whereas the inner helices of pore domain 2 are separated by ~50 Å across a short axis (Fig. 2B).

Fig. 2

Structure of TRAAK. (A) Left: Ribbon representation of a single TRAAK protomer viewed from the membrane plane with the extracellular solution above. Approximate positions of the lipid bilayer boundaries are indicated as gray bars. Pore domain 1 is colored blue, pore domain 2 is colored orange, and potassium ions are shown as green spheres. Right: Illustration of TRAAK protomer organization. Approximate boundaries of structural features are indicated in the illustration and labeled in the structure: N and C terminus, outer helix (OH), helical cap, pore helix (PH), selectivity filter (F), and inner helix (IH). (B) A view of the TRAAK channel from the cytoplasmic solution. The protomer shown in (A) is rotated 90° both into the page and clockwise, and the second protomer is half-transparent. (C) Stereo view of TRAAK viewed from the membrane plane with the protomer shown in (A) rotated 90°. The disulfide bond bridging the apex of the helical cap is shown in stick representation, with the cysteine sulfur colored yellow. Note that part of the cytoplasmic extension of protomer B (residues 180 to 187) is not present in the final TRAAK model because of weak electron density features. Here, it is modeled from a superposition of the well-defined region in protomer A for visual clarity. Loops not modeled in the structure because of a lack of interpretable electron density are drawn as dashed gray lines.

Structural asymmetry in TRAAK. Structural differences between pore domains 1 and 2 in each protomer of TRAAK result in deviation from the four-fold symmetry of known K+ channel structures and generate an approximately two-fold symmetric channel instead (Fig. 2C). Differences between TRAAK pore domains 1 and 2 are most evident in three regions: the outer helix–pore helix connection, the filter–inner helix connection, and the inner helix (fig. S7A).

The difference between the outer helix–pore helix connections in pore domains 1 and 2 is shown in fig. S7B. In pore domain 1, the ~60–amino acid connection forms a two-helix hairpin extending ~35 Å into the extracellular solution. The helices from each protomer pack together to form the helical cap and are covalently linked by a disulfide bond between interhelix turns at the cap apex. A conserved glycine allows a tight turn at the bottom of the second helix leading to an extended loop containing the N-linked glycosylation sites and connecting to the pore helix. The outer helix–pore helix connection in pore domain 2 forms a short four-residue linker structurally similar to the corresponding “turret” regions in the prokaryotic K+ channel MthK (25) and the nonselective cation channel NaK (26) (fig. S8).

The difference between the selectivity filter–inner helix connections in pore domains 1 and 2 is shown in fig. S7C. In pore domain 1, this connection is short and forms an interaction network conserved in most K+ channel structures tethering the extracellular end of the outer helix and inner helix (fig. S9), whereas in pore domain 2, this connection is longer and forms an extended bridge to the inner helix. The interaction network observed in pore domain 1 is absent because of the extended linker and lateral displacement of the pore domain 2 inner helix from the channel core.

The difference between the inner helices in pore domains 1 and 2 is shown in fig. S7D. The pore domain 1 inner helix is kinked halfway through the bilayer and projects toward the cytoplasmic side at an angle ~25° more acute to the membrane plane than the pore domain 2 inner helix. Pro155, two residues C-terminal to the hinge glycine conserved in all K+ channels, permits this helix distortion because of its lack of a hydrogen bond donor at the backbone amide position. Pro155 is conserved in K2P channel pore domain 1 inner helices [except in THIK-1,2 (fig. S2)] and not observed in pore domain 2 or in other ion channels. The pore domain 1 inner helix is also longer by three helical turns that lead to the cytoplasmic connection between pore domains 1 and 2.

Convergent four-fold symmetry at the selectivity filter. The pore helix and selectivity filter are the most conserved regions of K+ channels. The majority of K+ channel selectivity filters share the canonical sequence Thr-x-Gly-Tyr-Gly-Asp-x (where x denotes a hydrophobic amino acid). In TRAAK, the selectivity filter is made from the sequences Thr-Val-Gly-Tyr-Gly-Asn-Tyr (pore domain 1) and Thr-Ile-Gly-Phe-Gly-Asp-Val (pore domain 2). Comparison of TRAAK to the prototypical K+ channel KcsA (27) demonstrates that the overall two-fold symmetric channel converges to an essentially four-fold symmetric pore helix and selectivity filter (Fig. 3). Only minor deviations due to conservative side chain substitutions between the two TRAAK pore domains were observed. The atomic positions of K+ coordinating oxygens from selectivity filter residues in TRAAK align well with those from KcsA (root mean square deviation = 0.6 Å). We modeled four K+ ions in positions S1 to S4 and a fifth ion in the extracellular site S0 on the basis of observed electron density from native crystals grown in 150 mM KCl, Tl+ positions in derivative crystals determined from anomalous scattering data, and chemical knowledge of the ion conduction pathway. The convergence to nearly perfect four-fold symmetry at the pore helix and selectivity filter in the two-fold symmetric TRAAK channel implies strong evolutionary pressures maintaining the integrity of nature’s solution to highly selective K+ conduction through an ion channel.

Fig. 3

Convergent symmetry of the TRAAK pore helices and selectivity filter. Stereo view, from the membrane plane with extracellular solution above, shows a comparison between the TRAAK and KcsA (27) pore helices and selectivity filters. Pore helices and selectivity filter chains closest to the viewer are removed. Pore helices are shown as wires and selectivity filters as backbone sticks. TRAAK pore domain 1 is blue, TRAAK pore domain 2 is orange, and KcsA is gray, with backbone carbonyl and threonine hydroxyl oxygen atoms from selectivity filter residues shown in red. K+ positions in TRAAK (green spheres) occupy canonical positions S0 to S4 from the extracellular to the intracellular side.

The TRAAK helical cap structure and implications for K+ access and pharmacology. The helical cap is unprecedented in ion channel structures and is likely a conserved feature of K2P channels. The interface between protomers is large (~850 Å2) and forms a complementary hydrophobic core (Fig. 4, A and B). The region is conserved in length among K2P channels, with residues that form the hydrophobic core more conserved than those that are solvent-exposed (fig. S2). The interprotomer disulfide-bonded cysteine is conserved in most K2P channels (fig. S2) and was correctly predicted to covalently link TWIK protomers (28). The TRAAK helical cap is modestly askew of the molecular two-fold axis along the ion conduction pathway. This is presumably the result of crystal packing between the helical cap from one channel and a neighboring channel in the crystal (fig. S6). As a result, residues 55 to 60 from one protomer are extended, whereas the rest of the cap displays approximate two-fold symmetry.

Fig. 4

The TRAAK helical cap. (A) Stereo view of the helical cap viewed from the membrane plane with the extracellular solution above. TRAAK is shown as gray ribbons, with the helical cap blue within a semitransparent surface representation. A Tl+ anomalous-difference Fourier map (red mesh) calculated from 30 to 4.2 Å and contoured at 6σ is shown around Tl+ ions (red spheres). (B) The hydrophobic core of the helical cap. The helical cap is shown as a blue ribbon with hydrophobic residues (L65, F72, L73, P77, L84, L87, I88, V91, A92, A94) as green sticks. The C78 disulfide bond is shown as blue sticks with yellow sulfur atoms. Abbreviations: A, Ala; C, Cys; F, Phe; I, Ile; L, Leu; P, Pro; V, Val. (C) Cartoon depiction of the bifurcated ion pathway created by the TRAAK helical cap. View is analogous to (A). TRAAK (black) in a membrane (gray) coordinates four ions (red circles) in the selectivity filter and one ion directly above in site S0. A sixth ion is present in one of the two possible extracellular access/egress pathways (red arrows) that extend into the page and toward the viewer. The TRAAK helical cap blocks ion access from above and laterally in the image plane.

What might be the functional ramifications of the helical cap? The rigid helical bundle of the cap is positioned above the mouth of the channel pore tethered to pore domain 1 outer helices, bridging opposite sides of the channel. The surface of the helical cap is far enough above the pore entrance to allow unhindered K+ access from two sides. However, the cap blocks K+ access from above and from the two tethered sides, creating a bifurcated extracellular pathway for ions to the pore (Fig. 4, A and C). Consistently, we observed a Tl+ ion along one branch of the split pathway to the pore in crystals grown in the presence of TlNO3 in place of KCl (Fig. 4, A and C).

K2P channels are not responsive to known K+ channel blockers including pore-blocking toxins from the extracellular side (6, 16). The TRAAK structure provides a simple explanation for these observations: The presence of the helical cap above the pore would sterically prevent toxin access to the channel mouth. A similar steric occlusion mechanism was proposed for Kir2.2 on the basis of its atypically tall turrets surrounding the pore entrance (29). By fully preventing access to the mouth of the channel from above and two sides, the helical cap in K2P channels more effectively restricts molecular access to the pore entryway.

Implications of TRAAK structure for channel gating. The crystal structure of TRAAK has an open inner helical gate (Fig. 2C). The central cavity under the selectivity filter is wide and forms a vestibule continuous with the cytoplasmic solution, presenting no steric hindrance to ion flux. The pore domain 1 inner helices are wide open, with the smallest constriction measuring ~12 Å, similar to the most open configuration observed in MthK (fig. S10) (25). The pore domain 2 inner helices are slightly less open, with the smallest constriction measuring ~10 Å, but this is still more open than observed in open-state Kv structures (fig. S10) (30).

It is interesting to speculate on the potential for inner helix gating in TRAAK. Recent studies have suggested that the closely related K2P TREK-1 has an inner gate that is constitutively open (31, 32). Three features of the TRAAK pore domain 1 inner helix may be relevant if TRAAK has a similarly constitutively open inner gate: the presence of Pro155 that kinks the helix, the nature of the putative membrane interaction region (discussed below), and the peptide linkage to the pore domain 2 outer helix. The combination of these structural features may restrict the ability of the pore domain 1 inner helix to access a closed inner gate conformation.

TRAAK (and TREK) channels are exquisitely responsive to the chemical and mechanical properties of the lipid bilayer. Chemically, TRAAK is activated by arachidonic acid, other polyunsaturated fatty acids, and lysophosphatidic acid by an apparently direct mechanism (16, 3335). Mechanically, applying the equivalent to positive (and not negative) intracellular pressure through a patch pipette reversibly activates TRAAK and TREK (21, 34), whereas hyperosmolarity-induced cell shrinkage reduces TREK currents (20). Pressure-induced activation of TRAAK is enhanced upon cytoskeletal disruption or patch excision, which suggests that TRAAK directly responds to the physical state of the bilayer (21).

What might be the molecular sensor(s) of the mechanical and chemical state of the bilayer in TRAAK? In TREK channels, a region immediately C-terminal to the intracellular end of the pore domain 2 inner helix has been demonstrated to be involved in activity modulation by mechanical force, lipids and fatty acids, acidic internal pH (pHi), phosphorylation, and interaction with the accessory protein AKAP150 (20, 3640). The homologous C-terminal region in TRAAK is included in the crystal construct and is partially modeled as a cytoplasmic extension of the pore domain 2 inner helix (Fig. 2). However, this region has not been shown to be involved in TRAAK modulation: TRAAK is not activated by acidic pHi, TRAAK does not interact with AKAP150, and chimeras exchanging this region with that from TASK K2P channels display unaltered response to arachidonic acid and mechanical force (34, 36, 39, 41). Together, these data suggest that an alternative molecular sensor is used for TRAAK lipid activation and mechano-activation.

A distinctive structural feature of TRAAK is illustrated in Fig. 5A. After the kink at Pro155, the pore domain 1 inner helix projects laterally and runs approximately parallel to the cytoplasmic membrane surface. Along this projection the helix is amphipathic. Hydrophobic residues point toward the lipid bilayer along one face opposite a series of basic residues (Arg167, Arg173, His174, His178) pointed toward the membrane-cytoplasm interface. An additional basic residue (Lys185) farther along the helix is also directed toward the same plane. These five residues are conserved in basic character among TRAAK channels (fig. S3). The amphipathic helix is thus positioned to interact with both the hydrophobic tails and acidic head groups of membrane lipids. This structured extension of the pore domain 1 inner helix, which extends like a tendril out into the lipid membrane inner leaflet, may be related to this channel’s ability to respond to both mechanical and chemical properties of the cell membrane.

Fig. 5

TRAAK channel inner helices and gating implications. (A) View from the membrane, with extracellular solution above, of the amphipathic segment of the pore domain 1 inner helix (as in Fig. 1C). TRAAK is shown in wire representation with inner helices from pore domain 1 as ribbons and key residues as sticks within a semitransparent gray surface. Pore domain 1 is colored blue, pore domain 2 is colored orange, and K+ ions are shown as green spheres. The hinge glycine (Gly153), kink proline (Pro155), and hydrophobic face of the amphipathic segment (Leu168, Leu172, Ile176, Ile179, Ile182, Phe183, Trp186) are colored green. Basic residues conserved in TRAAK (Arg167, Arg173, His174, His178, Lys185) on the solution accessible face of the amphipathic helix are colored blue. (B) A view rotated 90° with respect to (A). The lipid bilayer accessible surface of the lateral opening into the TRAAK channel central cavity closest to the viewer is additionally colored yellow.

Another consequence of the inner helix structure in TRAAK is illustrated in Fig. 5B. The relative orientation of inner helices creates an extended lateral opening to the central cavity from the membrane. Between the two protomers, a gap ~5 Å wide extends through the bilayer from the bottom of the selectivity filter to the ends of the pore domain 2 inner helix and pore domain 1 outer helix on the cytoplasmic side. Although we observed electron density from the central cavity to the lateral openings in TRAAK, we were not able to confidently assign and model a ligand at this resolution. Lateral openings have been observed in other ion channels, including the K+ channel KcsA (27) and the voltage-gated sodium channel (42), but the size and shape of the openings in TRAAK are striking. This bilayer-facing opening results in a large protein surface accessible to the membrane and is a potential site for the interaction of lipids and other hydrophobic molecules with the TRAAK channel.

Supporting Online Material

Materials and Methods

Figs. S1 to S10

Table S1

References (4358)

References and Notes

  1. Acknowledgments: We thank M. Becker, R. Sanishvili, and staff at beamline 23-IDB/D at the Advanced Photon Source (APS), F. Murphy, K. Rajashankar, and staff at beamline 24-IDC at APS, and H. Robinson and staff at beamline X29 at the National Synchrotron Light Source for assistance at the synchrotrons, and members of the MacKinnon laboratory for helpful discussions. S.G.B. is a postdoctoral fellow of the Helen Hay Whitney Foundation, J.d.M. is a Howard Hughes Medical Institute International Student Research Fellow, and R.M. is an investigator in the Howard Hughes Medical Institute. The authors declare no conflict of interest. The x-ray crystallographic coordinates and structure factors are available in the Protein Data Bank, entry 3UM7. S.G.B. purified and crystallized TRAAK; collected, processed, and refined crystallographic data; and performed the flux assay and analyzed data. J.M. performed and analyzed data from electrophysiology experiments in CHO cells. R.M. performed and analyzed data from bilayer experiments. S.G.B and R.M. wrote the paper.

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