Modulation of BK(Ca) channel activity by fatty acids: structural requirements and mechanism of action

To determinethe mechanism of fatty acid modulation of rabbit pulmonary arterylarge-conductance Ca²⁺-activated K⁺(BK_Ca) channel activity, we studied effects of fatty acidsand other lipids on channel activity in excised patches withpatch-clamp techniques. The structural features of the fatty acidrequired to increase BK_Ca channel activity (or averagenumber of open channels, NP_o) were identified tobe the negatively charged head group and a sufficiently long (C > 8) carbon chain. Positively charged lipids like sphingosine, which havea sufficiently long alkyl chain (C  8), produced a decrease inNP_o. Neutral and short-chain lipids did notalter NP_o. Screening of membrane surface chargewith high-ionic-strength bathing solutions (330 mM K⁺ or130 mM K⁺, 300 mM Na⁺) did not alter themodulation of the BK_Ca channel NP_oby fatty acids and other charged lipids, indicating that channelmodulation is unlikely to be due to an alteration of the membraneelectric field or the attraction of local counterions to the channel.Fatty acids and other negatively charged lipids were able to modulate BK_Ca channel activity in bathing solutions containing 0 mMCa²⁺, 20 mM EGTA, suggesting that calcium is not requiredfor this modulation. Together, these results indicate that modulationof BK_Ca channels by fatty acids and other charged lipidsmost likely occurs by their direct interaction with the channel proteinitself or with some other channel-associated component.

     

Two novel cardiac atrial K+ channels, IK.AA and IK.PC

Two K(+)-selective channels in neonatal rat atrial cells activated by lipophilic compounds have been characterized in detail. The arachidonic acid-stimulated channel (IK.AA) had a slope conductance of 124 +/- 17 pS at +30 mV in symmetrical 140 mM potassium and a mean open time of approximately 1 ms, and was relatively voltage independent. IK.AA activity was reversibly increased by lowering pH to 6.0. Arachidonic acid was most effective in activating this channel, although a number of lipophilic compounds resulted in activation. Surprisingly, choline, a polar molecule, also activated the channel. A second K+ channel was activated by 10 microM phosphatidylcholine applied to the intracellular surface of inside-out atrial patches. This channel (IK.PC) had a slope conductance of 60 +/- 6 pS at +40 mV and a mean open time of approximately 0.6 ms, and was also relatively voltage independent. Fatty acids are probably monomeric in the membrane under the conditions of our recording; thus detergent effects are unlikely. Since a number of compounds including fatty acids and prostaglandins activated these two channels, an indirect, channel-specific mechanism may account for activation of these two cardiac K+ channels.     

Site of action of fatty acids and other charged lipids on BKCa channels from arterial smooth muscle cells

Fattyacids and other negatively charged single-chain lipids increaselarge-conductance Ca²⁺-activated K⁺(BK_Ca) channel activity, whereas sphingosine and otherpositively charged single-chain lipids suppress activity. Because thesemolecules are effective on both inside-out and outside-out patches andbecause they can flip across the bilayer, the location of their site of action is unclear. To identify the site of action of charged lipids onthis channel, we used two compounds that are unlikely to flip acrossthe lipid bilayer. Palmitoyl coenzyme A (PCoA) was used to identify thesite of action of negatively charged lipids, and a positively chargedmyristoylated pentapeptide (myr-KPRPK) was used to investigate the siteof action of positively charged lipids. The effect of these compoundson channel activity was studied in excised patches using patch-clamptechniques. In "normal" ionic strength solutions and in experimentswhere high-ionic strength solutions were used to shield membranesurface charge, PCoA increased channel activity only when applied tooutside-out patches, suggesting that the site of action of negativelycharged lipids is located on the outer surface of the membrane. Adecrease in activity, similar to that of other positively chargedlipids, was observed only when myr-KPRPK was applied to outside-outpatches, suggesting that positively charged lipids suppress activity byalso acting on the outer membrane surface. Some channel blockadeeffects of myr-KPRPK and KPRPK are also described. The sidedness ofaction suggests that modulation of channel activity by single-chainlipids can occur by their interaction with the channel protein.

     

Regulation of transmembrane ion transport by reaction products of phospholipase A2. II. Effects of arachidonic acid and other fatty acids on mitochondrial Ca2+ transport

The effects of arachidonic acid and other fatty acids on mitochondrial Ca2+ transport were studied. Cis-unsaturated fatty acids generally strongly inhibited mitochondrial Ca2+ uptake, induced a net Ca2+ efflux, and thereby increased the extramitochondrial Ca2+ concentration, whereas trans-unsaturated fatty acids were ineffective. Saturated fatty acids exhibited slight activity at chain lengths from C(10) to C(14) only. The structure-activity relationship and the inability of some of the effective fatty acids such as palmitoleic and myristoleic acid to be metabolized to eicosanoids suggest that Ca2+ release was induced by the fatty acids themselves and resulted from changes in the mitochondrial membrane bilayer structure. There was a correlation between Ca2+-releasing potency and reduction of mitochondrial membrane potential, which is the main driving force for mitochondrial Ca2+ uptake. There were, however, considerable differences compared with the effects of lysophospholipids on the membrane potential. The mechanism of action of fatty acids may be that of a fluidizing effect on the hydrophobic core of the membrane, thereby modulating the activity of integral membrane proteins of the respiratory chain.     

Dissection of antibacterial and toxic activity of melittin: a leucine zipper motif plays a crucial role in determining its hemolytic activity but not antibacterial activity

Melittin, a naturally occurring antimicrobial peptide, exhibits strong lytic activity against both eukaryotic and prokaryotic cells. Despite a tremendous amount of work done, very little is known about the amino acid sequence, which regulates its toxic activity. With the goal of understanding the basis of toxic activity and poor cell selectivity in melittin, a leucine zipper motif has been identified. To evaluate the possible structural and functional roles of this motif, melittin and its two analogs, after substituting the heptadic leucine by alanine, were synthesized and characterized. Functional studies indicated that alanine substitution in the leucine zipper motif resulted in a drastic reduction of the hemolytic activity of melittin. However, interestingly, both the designed analogs exhibited antibacterial activity comparable to melittin. Mutations caused a significant decrease in the membrane permeability of melittin in zwitterionic but not in negatively charged lipid vesicles. Although both the analogs exhibited similar secondary structures in the presence of negatively charged lipid vesicles as melittin, they failed to adopt a significant helical structure in the presence of zwitterionic lipid vesicles. Results suggest that the substitution of heptadic leucine by alanine impaired the assembly of melittin in an aqueous environment and its localization only in zwitterionic but not in negatively charged membrane. Altogether, the results suggest the identification of a structural element in melittin, which probably plays a prominent role in regulating its toxicity but not antibacterial activity. The results indicate that cell selectivity in some antimicrobial peptides can probably be introduced by modulating their assembly in an aqueous environment.     

Effects of vanadate, menadione and menadione analogs on the Ca2+-activated K+ channels in human red cells. Possible relations to membrane-bound oxidoreductase activity

The modulation of the Ca2+- (or Pb2+-)activated K+ permeability in human erythrocytes by vanadate, menadione and chloro-substituted menadione analogs was investigated by measurements of K+ fluxes and single-channel currents. Vanadate and menadione stimulate the K+ permeability by increasing the probability of channel openings; the menadione analogs, on the other hand, inhibit the K+ permeability by increasing the probability of channel closings. The compounds used in these experiments also interact with oxidoreductases; it is demonstrated that menadione analogs in contrast to menadione strongly inhibit the membrane-bound dehydrogenase in the erythrocytes. Concentrations of Pb2+ above 10 mumol/l, but not of Ca2+, inhibit the enzyme activity as well as the K+ permeability. The parallel effects on dehydrogenase activity and the K+ channels suggest a direct relationship between these two systems in the membrane of erythrocytes.     

Effects of fluorophore structure and hydrophobicity on the uptake and metabolism of fluorescent lipid analogs

Cellular transport and metabolism of fatty acids are integral components of lipid metabolism, but the mechanisms and regulation involved are poorly understood. A variety of commercially available fluorescent analogs of fatty acids, are potentially useful probes for the study of lipid metabolism by such techniques as cell sorting and fluorescence microscopy. We have screened a series of fluorescent fatty acids to identify analogs that would reliably simulate the metabolic behavior of natural fatty acids; i.e., similar kinetics of transport, of intracellular movement, and of metabolic fate. The metabolic behavior of these analogs was compared with those of some naturally occurring fatty acids in HepG2 cells, which are a good model of some aspects of hepatic function. Fluorescent analogs containing polar fluorophores yielded the lowest rates of cellular uptake and conversion to acylated lipid products. Similarly, fluorescent analogs with the fluorophore located near the carboxylic acid group were poorly metabolized. Fatty acid analogs containing anthracene or pyrene at the n-terminus of the acyl chain were the most extensively incorporated into cellular lipids. The types and amounts of labeled lipid products formed from these analogs and from natural fatty acids were similar. Pyrene-labeled analogs have spectral properties that can be measured fluorometrically at very low concentrations. Therefore, we compared the cellular metabolism of 12-(1-pyrenyl)dodecanoic acid with those of palmitic and oleic acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of insulin release by ionic and electrical events in B cells

This review article is an attempt to schematize the major alterations in ionic fluxes and B cell membrane potential that underlie the changes in insulin release brought about by glucose and by other stimulators or inhibitors. Glucose metabolism in B cells leads to closure of K channels in the plasma membrane. The resulting decrease in K+ permeability causes depolarization with activation of voltage-dependent Ca channels. An increase in Ca2+ influx ensues, which raises the cytoplasmic concentration of free Ca2+ and ultimately triggers insulin release. Tolbutamide induces a similar sequence of events by a direct action on K channels. In contrast, diazoxide antagonizes the effects of glucose by increasing K+ permeability of the B cell membrane. Among amino acids, leucine largely mimics the effects of glucose, whereas arginine depolarizes the B cell membrane because of its transport in a positively charged form.     

Fatty acid-activated K+ channels in autonomic neurons: activation by an endogenous source of free fatty acids

Application of arachidonic acid evoked robust activation of large-conductance K+ channels in cell-attached and excised inside-out patches from acutely isolated chick ciliary ganglion neurons. A similar effect was produced by 5,8,11,14-eicosatetraynoic acid, a nonmetabolizable analogue of arachidonic acid. The unitary conductance of fatty acid-activated channels was 35-40 pS at +20 mV with physiological gradients of K+ and 165 pS at +20 mV with an extracellular K+ concentration of 37.5 mM and an intracellular K+ concentration of 150 mM. Gating of these channels in cell-attached patches was potentiated by membrane stretch. Channel gating evoked by both lipids was concentration-dependent, with detectable activation apparent at 4 microM in the majority of patches and maximal activation occurring between 32 and 64 microM. Gating was relatively voltage-independent. Large-conductance K+ channels were also activated in inside-out patches by the monounsaturated fatty acid 11-cis-eicosenoic acid but not by the fully saturated fatty acid arachidic acid. Application of 100 microM H2O2, an agent that activates cytosolic phospholipase A2, also caused activation of large-conductance K+ channels in intact neurons. The stimulatory effects of H2O2 were blocked by pretreatment with 20 microM 4-bromophenacyl bromide, an irreversible inhibitor of phospholipase A2. Therefore, mobilization of endogenous fatty acids can cause activation of large-conductance K+ channels in autonomic neurons.     

Effects of phospholipid surface charge on ion conduction in the K+ channel of sarcoplasmic reticulum.

Single-channel K+ currents through sarcoplasmic reticulum K+ channels were compared after reconstitution into planar bilayers formed from neutral or negatively charged phospholipids. In neutral bilayers, the channel conductance saturates with K+ concentration according to a rectangular hyperbola, with half-saturation at 40 mM K+, and maximum conductance of 220 pS. In negatively charged bilayers (70% phosphatidylserine/30% phosphatidylethanolamine), the conductance is, at a given K+ concentration, higher than in neutral bilayers. This effect of negative surface charge is increasingly pronounced at lower ionic strength. The maximum conductance at high K+ approaches 220 pS in negative bilayers, and the channel's ionic selectivity is unaffected by lipid charge. The divalent channel blocker " bisQ11 " causes discrete blocking events in both neutral and negatively charged bilayers; the apparent rate constant of blocking is sensitive to surface charge, while the unblocking rate is largely unaffected. Bilayers containing a positively charged phosphatidylcholine analogue led to K+ conductances lower than those seen in neutral bilayers. The results are consistent with a simple mechanism in which the local K+ concentration sensed by the channel's entryway is determined by both the bulk K+ concentration and the bulk lipid surface potential, as given by the Gouy-Chapman model of the electrified interface. To be described by this approach, the channel's entryway must be assumed to be located 1-2 nm away from the lipid surface, on both sides of the membrane.     

Lipid and mechano-gated 2P domain K(+) channels.

The two pore domain K(+) channels TREK and TRAAK are opened by membrane stretch. The activating mechanical force comes from the bilayer membrane and is independent of the cytoskeleton. Emerging work shows that mechano-gated TREK and TRAAK are opened by various lipids, including long chain polyunsaturated anionic fatty acids and neutral cone-shaped lysophospholipids. TREK-1 shares the properties of the Aplysia neuronal S channel, a presynaptic background K(+) channel involved in behavioral sensitization, a simple form of learning.     

Translocation of fatty acids across the basolateral rat liver plasma membrane is driven by an active potential-sensitive sodium-dependent transport system

In previous studies it was shown that hepatocellular uptake of fatty acids is mediated by a specific fatty acid binding membrane protein. To determine now directly the driving forces for their entry into hepatocytes, the uptake of a representative long chain fatty acid, [3H]oleate, by basolateral rat liver plasma membrane vesicles was examined. Influx of oleate was stimulated by increasing the Na+ concentration of the medium. In the presence of an inwardly directed Na+ gradient (NaSCN, NaNO3, NaCl) oleate was accumulated during the initial uptake phase (20 s) at a concentration of 1.4-1.9-fold that at equilibrium (overshoot). This activation of influx was not observed after replacement of Na+ by Li+, K+, or choline+. Na+-dependent oleate uptake was significantly stimulated by creation of a negative intravesicular potential, either by altering the accompanying anions or by valinomycin-induced K+ diffusion potentials, suggesting an electrogenic transport mechanism. Na+-dependent fatty acid uptake was temperature dependent, with maximal overshoots occurring at 37 degrees C, and revealed saturation kinetics with a Km of 83.1 nM and Vmax of 2.9 nmol X min-1 X mg protein-1. These studies demonstrate that the carrier-mediated hepatocellular uptake of fatty acids represents an active potential-sensitive Na+-fatty acid cotransport system.     

Preparation of functional group analogs of unsaturated fatty acids and their effects on the circadian rhythm of a fatty-acid-deficient mutant of Neurospora crassa

Functional group analogs of oleic, linoleic and linolenic acids were prepared by coverting their double bonds to dibromo, cyclopropyl, epoxy, methoxy, and, in the case of oleic acid, hydroxy groups. These compounds were supplemented to the bd csp cel strain of the mold Neurospora crassa. The cel mutation confers a partial requirement for saturated fatty acids and, also, perturbs the circadian rhythm of spore formation. For example, the period of bd csp cel's rhythm is dramatically lengthened upon supplementation by natural cis-unsaturated fatty acids. Of the analogs tested, only the monoepoxy, monomethoxy, dibromo, and hexabromo stearic acids gave significant period lengthening. Other analogs, which should have comparable abilities to disrupt lipid bilayer packing, gave no rhythm effect. Further, the inactive di- and tri-methoxystearic acid analogs were incorporated to a greater extent than the active mono-methoxystearic acid. The results do not, therefore, support a direct alteration in membrane "fluidity' as the mode of action of the period-lengthening fatty acids.     

Effects of long-chain cis-unsaturated fatty acids and their alcohol analogs on aggregation of bovine platelets and their relation with membrane fluidity change

The effects of long-chain cis-unsaturated fatty acids with different alkyl chain lengths and different numbers of double bonds on aggregation of bovine platelets and membrane fluidity were investigated. All the cis-unsaturated fatty acids tested inhibited aggregation and at the same time increased membrane fluidity in accordance with their inhibitory effects. The saturated fatty acids and trans-unsaturated fatty acid tested for comparison had much lower or no effects on aggregation and membrane fluidity. The inhibitory effects of mono cis-unsaturated fatty acids increased with increase of their alkyl chain length. cis-Unsaturated fatty acids with two or more double bonds had more inhibitory effects than mono-unsaturated fatty acids. The position of the double bonds had less influence than the number of double bonds. We also examined the effects of cis-unsaturated fatty acids on membrane fluidity with diphenylhexatriene and anthroyloxy derivatives of fatty acids as probes and observed increased fluidity to be considerable in the membrane. The alcohol analogs of cis-unsaturated fatty acids also inhibited aggregation and increased membrane perturbation. These results suggest that the inhibition of platelet aggregation by cis-unsaturated compounds is due to perturbation of the lipid layer.     

Conduction through the inward rectifier potassium channel, Kir2.1, is increased by negatively charged extracellular residues

Ion channel conductance can be influenced by electrostatic effects originating from fixed "surface" charges that are remote from the selectivity filter. To explore whether surface charges contribute to the conductance properties of Kir2.1 channels, unitary conductance was measured in cell-attached recordings of Chinese hamster ovary (CHO) cells transfected with Kir2.1 channels over a range of K+ activities (4.6-293.5 mM) using single-channel measurements as well as nonstationary fluctuation analysis for low K+ activities. K+ ion concentrations were shown to equilibrate across the cell membrane in our studies using the voltage-sensitive dye DiBAC4(5). The dependence of gamma on the K+ activity (a(K)) was fit well by a modified Langmuir binding isotherm, with a nonzero intercept as a(K) approaches 0 mM, suggesting electrostatic surface charge effects. Following the addition of 100 mM N-methyl-D-glucamine (NMG+), a nonpermeant, nonblocking cation or following pretreatment with 50 mM trimethyloxonium (TMO), a carboxylic acid esterifying agent, the gamma-a(K) relationship did not show nonzero intercepts, suggesting the presence of surface charges formed by glutamate or aspartate residues. Consistent with surface charges in Kir2.1 channels, the rates of current decay induced by Ba2+ block were slowed with the addition of NMG or TMO. Using a molecular model of Kir2.1 channels, three candidate negatively charged residues were identified near the extracellular mouth of the pore and mutated to cysteine (E125C, D152C, and E153C). E153C channels, but not E125C or D152C channels, showed hyperbolic gamma-a(K) relationships going through the origin. Moreover, the addition of MTSES to restore the negative charges in E53C channels reestablished wild-type conductance properties. Our results demonstrate that E153 contributes to the conductance properties of Kir2.1 channels by acting as a surface charge.     

Relationship between (Na + K)-ATPase activity, lipid peroxidation and fatty acid profile in erythrocytes of hypertensive and normotensive subjects

Oxidative stress may play a role in the pathogenic mechanism of essential hypertension. Lipid peroxidation can alter the cellular structure of membrane-bound enzymes by changing the membrane phospholipids fatty acids composition. We investigated the relationship between (Na + K)-ATPase activity, lipid peroxidation, and erythrocyte fatty acid composition in essential hypertension. The study included 40 essential hypertensive and 49 healthy normotensive men (ages 35–60 years). Exclusion criteria were obesity, dyslipidemia, diabetes mellitus, smoking, and any current medication. Patients underwent 24-h ambulatory blood pressure monitoring and blood sampling. Lipid peroxidation was measured in the plasma and erythrocytes as 8-isoprostane or malondialdehyde (MDA), respectively. Antioxidant capacity was measured as ferric reducing ability of plasma (FRAP) in the plasma and as reduced/oxidized glutathione (GSH/GSSG ratio) in erythrocytes. (Na + K)-ATPase activity and fatty acids were determined in erythrocyte membranes. Hypertensives had higher levels of plasma 8-isoprostane, erythrocyte MDA, and relative percentage of saturated membrane fatty acids, but lower plasma FRAP levels, erythrocyte GSH/GSSG ratio, (Na + K)-ATPase activity and relative percentage of unsaturated membrane fatty acids, compared with normotensives. Day-time systolic and diastolic blood pressures correlated positively with lipid peroxidation parameters, but negatively with (Na + K)-ATPase activity. These findings suggest that the modulation of (Na + K)-ATPase activity may be associated with changes in the fatty acid composition induced by oxidative stress and provide evidence of a role for this enzyme in the pathophysiology of essential hypertension.     

Long polyamines act as cofactors in PIP2 activation of inward rectifier potassium (Kir2.1) channels

Phosphatidylinosital-4,5-bisphosphate (PIP2) acts as an essential factor regulating the activity of all Kir channels. In most Kir members, the dependence on PIP2 is modulated by other factors, such as protein kinases (in Kir1), G(betagamma) (in Kir3), and the sulfonylurea receptor (in Kir6). So far, however, no regulator has been identified in Kir2 channels. Here we show that polyamines, which cause inward rectification by selectively blocking outward current, also regulate the interaction of PIP2 with Kir2.1 channels to maintain channel availability. Using spermine and diamines as polyamine analogs, we demonstrate that both spontaneous and PIP2 antibody-induced rundown of Kir2.1 channels in excised inside-out patches was markedly slowed by long polyamines; in contrast, polyamines with shorter chain length were ineffective. In K188Q mutant channels, which have a low PIP2 affinity, application PIP2 (10 microM) was unable to activate channel activity in the absence of polyamines, but markedly activated channels in the presence of long diamines. Using neomycin as a measure of PIP2 affinity, we found that long polyamines were capable of strengthening either the wild type or K188Q channels' interaction with PIP2. The negatively charged D172 residue inside the transmembrane pore region was critical for the shift of channel-PIP2 binding affinity by long polyamines. Sustained pore block by polyamines was neither sufficient nor necessary for this effect. We conclude that long polyamines serve a dual role as both blockers and coactivators (with PIP2) of Kir2.1 channels.     

p11, an annexin II subunit,an auxiliary protein associated with the background K+ channel,TASK-1

TASK-1 belongs to the 2P domain K+ channel family and is the prototype of background K+ channels that set the resting membrane potential and tune action potential duration. Its activity is highly regulated by hormones and neurotransmitters. Although numerous auxiliary proteins have been described to modify biophysical, pharmacological and expression properties of different voltage- and Ca2+-sensitive K+ channels, none of them is known to modulate 2P domain K+ channel activity. We show here that p11 interacts specifically with the TASK-1 K+ channel. p11 is a subunit of annexin II, a cytoplasmic protein thought to bind and organize specialized membrane cytoskeleton compartments. This association with p11 requires the integrity of the last three C-terminal amino acids, Ser-Ser-Val, in TASK-1. Using series of C-terminal TASK-1 deletion mutants and several TASK-1-GFP chimeras, we demonstrate that association with p11 is essential for trafficking of TASK-1 to the plasma membrane. p11 association with the TASK-1 channel masks an endoplasmic reticulum retention signal identified as Lys-Arg-Arg that precedes the Ser-Ser-Val sequence.