Pacemaker oscillations in heart and brain: a key role for hyperpolarization-activated cation channels

Rhythmic activity of single cells or multicellular networks is a common feature of all organisms. The oscillatory activity is characterized by time intervals of several seconds up to many hours. Cellular rhythms govern the beating of the heart, the swimming behavior of sperm, cycles of sleep and wakefulness, breathing, and the release of hormones. Many neurons in the brain and cardiac cells are characterized by endogenous rhythmic activity, which relies on a complex interplay between several distinct ion channels. In particular, one type of ion channel plays a prominent role in the control of rhythmic electrical activity since it determines the frequency of the oscillations. The activity of the channels is thus setting the "pace" of the oscillations; therefore, these channels are often referred to as "pacemaker" channels. Despite their obvious important physiological function, it was not until recently that genes encoding pacemaker channels have been identified. Because both hyperpolarization and cyclic nucleotides are key elements that control their activity, pacemaker channels have now been designated hyperpolarization-activated and cyclic nucleotide-gated (HCN) channels. The molecular identification of the channels and the upcoming studies on their properties in heterologous systems will certainly enhance our understanding of "pacemaking" in physiological systems. This review gives a brief insight into the physiological importance of these channels and sums up what we have learned since the first cloning of genes succeeded (for recent reviews, see also Clapham 1998; Luthi and McCormick 1998a; Biel et al. 1999; Ludwig, Zong, Hofmann, et al. 1999; Santoro and Tibbs 1999).     

Niflumic acid blocks native and recombinant T-type channels

Voltage‐dependent calcium channels are widely distributed in animal cells, including spermatozoa. Calcium is fundamental in many sperm functions such as: motility, capacitation, and the acrosome reaction (AR), all essential for fertilization. Pharmacological evidence has suggested T‐type calcium channels participate in the AR. Niflumic acid (NA), a non‐steroidal anti‐inflammatory drug commonly used as chloride channel blocker, blocks T‐currents in mouse spermatogenic cells and Cl^? channels in testicular sperm. Here we examine the mechanism of NA blockade and explore if it can be used to separate the contribution of different Ca_V3 members previously detected in these cells. Electrophysiological patch‐clamp recordings were performed in isolated mouse spermatogenic cells and in HEK cells heterologously expressing Ca_V3 channels. NA blocks mouse spermatogenic cell T‐type currents with an IC₅₀ of 73.5 µM, without major voltage‐dependent effects. The NA blockade is more potent in the open and in the inactivated state than in the closed state of the T‐type channels. Interestingly, we found that heterologously expressed Ca_V3.1 and Ca_V3.3 channels were more sensitive to NA than Ca_V3.2 channels, and this drug substantially slowed the recovery from inactivation of the three isoforms. Molecular docking modeling of drug‐channel binding predicts that NA binds preferentially to the extracellular face of Ca_V3.1 channels. The biophysical characteristics of mouse spermatogenic cell T‐type currents more closely resemble those from heterologously expressed Ca_V3.1 channels, including their sensitivity to NA. As Ca_V3.1 null mice maintain their spermatogenic cell T‐currents, it is likely that a novel Ca_V3.2 isoform is responsible for them. J. Cell. Physiol. 227: 2542–2555, 2012. © 2011 Wiley Periodicals, Inc.     

Involvement of hyperpolarization-activated, cyclic nucleotide-gated cation channels in dorsal root ganglion in neuropathic pain

Dorsal root ganglion(DRG)neurons have peripheral terminals in skin,muscle,and other peripheral tissues,andcentral terminals     

Involvement of hyperpolarization-activated, cyclic nucleotide-gated cation channels in dorsal root ganglion m neuropathic pain

Dorsal root ganglion DRG neurons have peripheral ter-minals in skin, muscle, and other peripheral tissues, andcentral terminals in the spinal cord dorsal horn.     

Blocker state dependence and trapping in hyperpolarization-activated cation channels: evidence for an intracellular activation gate

Hyperpolarization-activated cation currents (I(h)) are key determinants of repetitive electrical activity in heart and nerve cells. The bradycardic agent ZD7288 is a selective blocker of these currents. We studied the mechanism for ZD7288 blockade of cloned I(h) channels in excised inside-out patches. ZD7288 blockade of the mammalian mHCN1 channel appeared to require opening of the channel, but strong hyperpolarization disfavored blockade. The steepness of this voltage-dependent effect (an apparent valence of approximately 4) makes it unlikely to arise solely from a direct effect of voltage on blocker binding. Instead, it probably indicates a differential affinity of the blocker for different channel conformations. Similar properties were seen for ZD7288 blockade of the sea urchin homologue of I(h) channels (SPIH), but some of the blockade was irreversible. To explore the molecular basis for the difference in reversibility, we constructed chimeric channels from mHCN1 and SPIH and localized the structural determinant for the reversibility to three residues in the S6 region likely to line the pore. Using a triple point mutant in S6, we also revealed the trapping of ZD7288 by the closing of the channel. Overall, the observations led us to hypothesize that the residues responsible for ZD7288 block of I(h) channels are located in the pore lining, and are guarded by an intracellular activation gate of the channel.     

Regulation of gating and rundown of HCN hyperpolarization-activated channels by exogenous and endogenous PIP2

The voltage dependence of activation of the HCN hyperpolarization-activated cation channels is shifted in inside-out patches by -40 to -60 mV relative to activation in intact cells, a phenomenon referred to as rundown. Less than 20 mV of this hyperpolarizing shift can be due to the influence of the canonical modulator of HCN channels, cAMP. Here we study the role of phosphatidylinositol 4,5-bisphosphate (PI(4,5)P(2)) in HCN channel rundown, as hydrolysis of PI(4,5)P(2) by lipid phosphatases is thought to underlie rundown of several other channels. We find that bath application of exogenous PI(4,5)P(2) reverses the effect of rundown, producing a large depolarizing shift in HCN2 activation. A synthetic short chain analogue of PI(4,5)P(2), dioctanoyl phosphatidylinositol 4,5-bisphosphate, shifts the HCN2 activation curve to more positive potentials in a dose-dependent manner. Other dioctanoyl phosphatidylinositides with one or more phosphates on the lipid headgroup also shift activation, although phosphatidylinositol (PI) is ineffective. Several lines of evidence suggest that HCN2 is also regulated by endogenous PI(4,5)P(2): (a) blockade of phosphatases slows the hyperpolarizing shift upon patch excision; (b) application of an antibody that binds and depletes membrane PIP(2) causes a further hyperpolarizing shift in activation; (c) the shift in activation upon patch excision can be partially reversed by MgATP; and (d) the effect of MgATP is blocked by wortmannin, an inhibitor of PI kinases. Finally, recordings from rabbit sinoatrial cells demonstrate that diC(8) PI(4,5)P(2) delays the rundown of native HCN currents. Thus, both native and recombinant HCN channels are regulated by PI(4,5)P(2).     

Regulation of hyperpolarization-activated HCN channels by cAMP through a gating switch in binding domain symmetry

Recent X-ray structures show that the binding domains of tetrameric ligand-gated channels form either a 4-fold symmetric gating ring or a 2-fold symmetric dimer of dimers. To determine how such structures function to coordinate the binding of multiple ligands during channel activation, we examined the action of cAMP to enhance the opening of the hyperpolarization-activated HCN2 channels, whose cytoplasmic C terminus forms a gating ring in the presence of cAMP. Using tandem dimers and tetramers in which cAMP binding to selected HCN2 subunits was prevented by a point mutation or deletion, we provide the first direct determination of the energetic effects on gating of each of four ligand binding events and demonstrate the importance of the gating ring for cAMP regulation. We suggest that cAMP binding enhances channel opening by promoting assembly of the gating ring from an unliganded state in which the four subunits interact as a 2-fold symmetric dimer of dimers.     

Modeling-independent elucidation of inactivation pathways in recombinant and native A-type Kv channels

A-type voltage-gated K⁺ (Kv) channels self-regulate their activity by inactivating directly from the open state (open-state inactivation [OSI]) or by inactivating before they open (closed-state inactivation [CSI]). To determine the inactivation pathways, it is often necessary to apply several pulse protocols, pore blockers, single-channel recording, and kinetic modeling. However, intrinsic hurdles may preclude the standardized application of these methods. Here, we implemented a simple method inspired by earlier studies of Na⁺ channels to analyze macroscopic inactivation and conclusively deduce the pathways of inactivation of recombinant and native A-type Kv channels. We investigated two distinct A-type Kv channels expressed heterologously (Kv3.4 and Kv4.2 with accessory subunits) and their native counterparts in dorsal root ganglion and cerebellar granule neurons. This approach applies two conventional pulse protocols to examine inactivation induced by (a) a simple step (single-pulse inactivation) and (b) a conditioning step (double-pulse inactivation). Consistent with OSI, the rate of Kv3.4 inactivation (i.e., the negative first derivative of double-pulse inactivation) precisely superimposes on the profile of the Kv3.4 current evoked by a single pulse because the channels must open to inactivate. In contrast, the rate of Kv4.2 inactivation is asynchronous, already changing at earlier times relative to the profile of the Kv4.2 current evoked by a single pulse. Thus, Kv4.2 inactivation occurs uncoupled from channel opening, indicating CSI. Furthermore, the inactivation time constant versus voltage relation of Kv3.4 decreases monotonically with depolarization and levels off, whereas that of Kv4.2 exhibits a J-shape profile. We also manipulated the inactivation phenotype by changing the subunit composition and show how CSI and CSI combined with OSI might affect spiking properties in a full computational model of the hippocampal CA1 neuron. This work unambiguously elucidates contrasting inactivation pathways in neuronal A-type Kv channels and demonstrates how distinct pathways might impact neurophysiological activity.     

Movements near the gate of a hyperpolarization-activated cation channel

Hyperpolarization-activated cation (HCN) channels regulate pacemaking activity in cardiac cells and neurons. Like the related depolarization-activated K+ channels (Kv channels), HCN channels use an intracellular activation gate to regulate access to an inner cavity, lined by the S6 transmembrane regions, which leads to the selectivity filter near the extracellular surface. Here we describe two types of metal interactions with substituted cysteines in the S6, which alter the voltage-controlled movements of the gate. At one position (L466), substitution of cysteine in all four subunits allows Cd2+ ions at nanomolar concentration to stabilize the open state (a "lock-open" effect). This effect depends on native histidines at a nearby position (H462); the lock-open effect can be abolished by changing the histidines to tyrosines, or enhanced by changing them to cysteines. Unlike a similar effect in Kv channels, this effect depends on a Cd2+ bridge between 462 and 466 in the same subunit. Cysteine substitution at another position (Q468) produces two effects of Cd2+: both a lock-open effect and a dramatic slowing of channel activation-a "lock-closed" effect. The two effects can be separated, because the lock-open effect depends on the histidine at position 462. The novel lock-closed effect results from stabilization of the closed state by the binding of up to four Cd2+ ions. During the opening conformational change, the S6 apparently moves from one position in which the 468C cysteines can bind four Cd2+ ions, possibly as a cluster of cysteines and cadmium ions near the central axis of the pore, to another position (or flexible range of positions) where either 466C or 468C can bind Cd2+ in association with the histidine at 462.     

Regulation of the mechanosensitive cation channels by ATP and cAMP in leech neurons

Single-channel recordings were used to study the modulation of stretch-activated channels (SACs) by intracellular adenosine nucleotides in identified leech neurons. These channels exhibited two activity modes, spike-like (SL) and multiconductance (MC), displaying different polymodal activation. In the absence of mechanical stimulation, internal perfusion of excised patches with ATP induced robust and reversible activation of the MC but not of the SL mode. The ATP effect on channel activity was dose-dependent within a range of 1 microM-1 mM and was induced at different values of intracellular pH and Ca2+. The non-hydrolyzable ATP analog AMP-PNP, ATP without Mg2+ or ADP also effectively enhanced MC activity. Adenosine mimicked the effect of its nucleotides. At negative membrane potentials, both ATP and adenosine activated the channel. Moreover, ATP but not adenosine induced a flickering block. Addition of cAMP during maximal ATP activation completely and reversibly inhibited the channel, with activation and deactivation times of minutes. However, cAMP alone only induced a weak and rapid channel activation, without inhibitory effects. The expression of these channels in the growth cones of leech neurons, their permeability to Ca2+ and their sensitivity to intracellular cAMP are consistent with a role in the Ca2+ oscillations associated with cell growth.     

Regulation of cation channels in cardiac and smooth muscle cells by intracellular magnesium

Magnesium regulates various ion channels in many tissues, including those of the cardiovascular system. General mechanisms by which intracellular Mg(2+) (Mg(i)(2+)) regulates channels are presented. These involve either a direct interaction with the channel, or an indirect modification of channel function via other proteins, such as enzymes or G proteins, or via membrane surface charges and phospholipids. To provide an insight into the role of Mg(i)(2+) in the cardiovascular system, effects of Mg(i)(2+) on major channels in cardiac and smooth muscle cells and the underlying mechanisms are then reviewed. Although Mg(i)(2+) concentrations are known to be stable, conditions under which they may change exist, such as following stimulation of beta-adrenergic receptors and of insulin receptors, or during pathophysiological conditions such as ischemia, heart failure or hypertension. Modifications of cardiovascular electrical or mechanical function, possibly resulting in arrhythmias or hypertension, may result from such changes of Mg(i)(2+) and their effects on cation channels.     

Regulation of the mechanosensitive cation channels by ATP and cAMP in leech neurons

Single-channel recordings were used to study the modulation of stretch-activated channels (SACs) by intracellular adenosine nucleotides in identified leech neurons. These channels exhibited two activity modes, spike-like (SL) and multiconductance (MC), displaying different polymodal activation. In the absence of mechanical stimulation, internal perfusion of excised patches with ATP induced robust and reversible activation of the MC but not of the SL mode. The ATP effect on channel activity was dose-dependent within a range of 1 μM-1 mM and was induced at different values of intracellular pH and Ca²⁺. The non-hydrolyzable ATP analog AMP-PNP, ATP without Mg²⁺ or ADP also effectively enhanced MC activity. Adenosine mimicked the effect of its nucleotides. At negative membrane potentials, both ATP and adenosine activated the channel. Moreover, ATP but not adenosine induced a flickering block. Addition of cAMP during maximal ATP activation completely and reversibly inhibited the channel, with activation and deactivation times of minutes. However, cAMP alone only induced a weak and rapid channel activation, without inhibitory effects. The expression of these channels in the growth cones of leech neurons, their permeability to Ca²⁺ and their sensitivity to intracellular cAMP are consistent with a role in the Ca²⁺ oscillations associated with cell growth.     

Characteristics of hyperpolarization-activated cation currents in portal vein smooth muscle cells

Voltage-clamp studies offreshly isolated smooth muscle cells from rabbit portal veinrevealed the existence of a time-dependent cation current evoked bymembrane hyperpolarization (termed I_h). Both therate of activation and the amplitude of I_h wereenhanced by membrane hyperpolarization. Half-maximal activation ofI_h was about 105 mV with conventional wholecell and 80 mV when the perforated patch technique was used. Incurrent clamp, injection of hyperpolarizing current produced a markeddepolarizing "sag" followed by rebound depolarization. Activationof I_h was augmented by an increase in theextracellular K⁺ concentration and was blocked rapidly byexternally applied Cs⁺ (1-5 mM). The bradycardic agentZD-7288 (10 µM), a selective inhibitor of I_h,produced a characteristically slow inhibition of the portal veinI_h. The depolarizing sag recorded in current clamp was also abolished by application of 5 mM Cs⁺.Cs⁺ significantly decreased the frequency of spontaneouscontractions in both whole rat portal vein and rabbit portal veinsegments. Multiplex RT-PCR of rabbit portal vein myocytes using primers derived from existing genes for hyperpolarization-activated cation channels (HCN1-4) revealed the existence of cDNA clonescorresponding to HCN2, 3, and 4. The present study shows that portalvein myocytes contain genes shown to encode forhyperpolarization-activated channels and exhibit an endogenous currentwith characteristics similar to I_h in other celltypes. This conductance appears to determine, in part, the rhythmicityof this vessel.

     

Molecular characterization of the hyperpolarization-activated cation channel in rabbit heart sinoatrial node

We cloned a cDNA (HAC4) that encodes the hyperpolarization-activated cation channel (If or Ih) by screening a rabbit sinoatrial (SA) node cDNA library using a fragment of rat brain If cDNA. HAC4 is composed of 1150 amino acid residues, and its cytoplasmic N- and C-terminal regions are longer than those of HAC1-3. The transmembrane region of HAC4 was most homologous to partially cloned mouse If BCNG-3 (96%), whereas the C-terminal region of HAC4 showed low homology to all HAC family members so far cloned. Northern blotting revealed that HAC4 mRNA was the most highly expressed in the SA node among the rabbit cardiac tissues examined. The electrophysiological properties of HAC4 were examined using the whole cell patch-clamp technique. In COS-7 cells transfected with HAC4 cDNA, hyperpolarizing voltage steps activated slowly developing inward currents. The half-maximal activation was obtained at -87.2 +/- 2.8 mV under control conditions and at -64.4 +/- 2.6 mV in the presence of intracellular 0.3 mM cAMP. The reversal potential was -34.2 +/- 0.9 mV in 140 mM Na+o and 5 mM K+o versus 10 mM Na+i and 145 mM K+i. These results indicate that HAC4 forms If in rabbit heart SA node.     

Antagonistic regulation of native Ca2+- and ATP-sensitive cation channels in brain capillaries by nucleotides and decavanadate

Regulation by cytosolic nucleotides of Ca2+- and ATP-sensitive nonselective cation channels (CA-NSCs) in rat brain capillary endothelial cells was studied in excised inside-out patches. Open probability (Po) was suppressed by cytosolic nucleotides with apparent KI values of 17, 9, and 2 microM for ATP, ADP, and AMP, as a consequence of high-affinity inhibition of channel opening rate and low-affinity stimulation of closing rate. Cytosolic [Ca2+] and voltage affected inhibition of Po, but not of opening rate, by ATP, suggesting that the conformation of the nucleotide binding site is influenced only by the state of the channel gate, not by that of the Ca2+ and voltage sensors. ATP inhibition was unaltered by channel rundown. Nucleotide structure affected inhibitory potency that was little sensitive to base substitutions, but was greatly diminished by 3'-5' cyclization, removal of all phosphates, or complete omission of the base. In contrast, decavanadate potently (K1/2 = 90 nM) and robustly stimulated Po, and functionally competed with inhibitory nucleotides. From kinetic analyses we conclude that (a) ATP, ADP, and AMP bind to a common site; (b) inhibition by nucleotides occurs through simple reversible binding, as a consequence of tighter binding to the closed-channel relative to the open-channel conformation; (c) the conformation of the nucleotide binding site is not directly modulated by Ca2+ and voltage; (d) the differences in inhibitory potency of ATP, ADP, and AMP reflect their different affinities for the closed channel; and (e) though decavanadate is the only example found to date of a compound that stimulates Po with high affinity even in the presence of millimolar nucleotides, apparently by competing for the nucleotide binding site, a comparable mechanism might allow CA-NSC channels to open in living cells despite physiological levels of nucleotides. Decavanadate now provides a valuable tool for studying native CA-NSC channels and for screening cloned channels.     

Functional analysis of native and recombinant ion channels using a high-capacity nonradioactive rubidium efflux assay.

A nonradioactive cell-based rubidium (Rb(+)) efflux assay for functional analysis of native and recombinant ion channels has been developed. Cells are first loaded with rubidium, a tracer for potassium, and after channel activation, rubidium distribution between intracellular and extracellular space is determined by atomic absorption spectroscopy. The relative amount of rubidium in the cell supernatant is a direct measure of channel activity. The broad utility of the method is demonstrated by analysis of a range of different ion channels. Ligand-gated ion channels like nicotinic acetylcholine receptors and purinergic P2X receptors were studied in native PC-12 cells. Calcium-activated potassium channels were analyzed in native (small-conductance calcium-activated potassium channel, SK(Ca)) as well as recombinant cell lines (large-conductance calcium-activated potassium channel, BK(Ca)). Also recombinant voltage-gated potassium channels (Kv1.1, Kv1.4) were amenable to this functional analysis. The method is particularly useful for identification of ion channel modulators in drug discovery since it allows functional analysis with high capacity.     

Structural elements of instantaneous and slow gating in hyperpolarization-activated cyclic nucleotide-gated channels

Hyperpolarization-activated cyclic nucleotide-gated (HCN) subunits produce a slowly activating current in response to hyperpolarization (If) and an instantaneous voltage-independent current (Iinst) when expressed in Chinese hamster ovary (CHO) cells. Here we found that a mutation in the S4-S5 linker of HCN2 (Y331D) produced an additional mixed cationic instantaneous current. However, this current was inhibited by external Cs+ like If and unlike Iinst. Together with a concomitant reduction in If, the data suggest that the Y331D mutation disrupted channel closing placing the channel in a "If-like," and not an "Iinst-like," state. The "If-like" instantaneous current represented approximately 70% of total If over voltages ranging from +20 to -150 mV in high K+ solutions. If activated at more depolarized potentials and the activation curve was less steep, whereas deactivation was significantly slowed, consistent with the idea that the mutation inhibited channel closing. The data suggest that the mutation produced allosteric effects on the activation gate (S6 segment) and/or on voltage-sensing elements. We also found that decreases in the ratio of external K+/Na+ further disrupted channel closing in the mutant channel. Finally, our data suggest that the structures involved in producing Iinst are similar between the HCN1 and HCN2 isoforms and that excess HCN protein on the plasma membrane of CHO cells relative to native cells is not responsible for Iinst. The data are consistent with Iinst flowing through a "leaky" closed state but do not rule out flow through a second configuration of recombinant HCN channels or up-regulated endogenous channels/subunits.     

The mammalian TRPC cation channels

Transient Receptor Potential-Canonical (TRPC) channels are mammalian homologs of Transient Receptor Potential (TRP), a Ca(2+)-permeable channel involved in the phospholipase C-regulated photoreceptor activation mechanism in Drosophila. The seven mammalian TRPCs constitute a family of channels which have been proposed to function as store-operated as well as second messenger-operated channels in a variety of cell types. TRPC channels, together with other more distantly related channel families, make up the larger TRP channel superfamily. This review summarizes recent findings on the structure, regulation and function of the apparently ubiquitous TRPC cation channels.