Sensitivity Of BK Channels Research Articles

Regulation Of BK Channels By FK506 Binding Protein 12.6 In Vascular Smooth Muscle Cells

Big-conductance, calcium-activated potassium (BK) channels are important for numerous physiological responses, including relaxation of vascular smooth muscle cells (SMCs). The activity of BK channels can be regulated by several signaling molecules. Here we provide biochemical evidence showing that FK506 binding protein 12.6 (FKBP12.6), an endogenous molecule known to regulate ryanodine receptors/calcium release channels, is physically associated with the BK channel α subunits in mouse cerebral arteries. Inside-out single channels recordings show that application of FK506 to remove FKBP12.6 significantly decreases the open probability of BK channels in freshly isolated mouse cerebral artery SMCs. The effect of FK506 is concentration-dependent. Similar to chemical removal of FKBP12.6 with FK506 exposure, genetic removal of FKBP12.6 with gene deletion produces an inhibitory effect on the activity of single BK channels as well. FKBP12.6 gene deletion also reduces the sensitivity of BK channels to voltage and calcium. Consistent with these results, agonist-evoked vasoconstriction is augmented in isolated arteries from FKBP2.6 gene deletion mice. Moreover, blood pressure is higher in FKBP12.6 gene deletion mice than control mice. In conclusion, our findings for the first time demonstrate that FKBP12.6 is associated with BK channels and regulates the channel functions, which may play an important role in controlling vascular tone and blood pressure.

Four-turn α-Helical Segment Prevents Surface Expression of the Auxiliary hβ2 Subunit of BK-type Channel

Large conductance, voltage- and Ca2+-activated K+ (BK) channels encoded by the mslo alpha and beta2 subunits exist abundantly in rat chromaffin cells, pancreatic beta cells, and DRG neurons. The extracellular loop of hbeta2 acting as the channel regulator influences the rectification and toxin sensitivity of BK channels, and the inactivation domain at its N terminus induces rapid inactivation. However, the regulatory mechanism, especially the trafficking mechanism of hbeta2, is still unknown. With the help of immunofluorescence and patch clamp techniques, we determine that the hbeta2 subunit alone resides in the endoplasmic reticulum, suggesting that trafficking mechanism of hbeta2 differs from that of hbeta1 opposite to what we predicted previously. We further demonstrate that a four-turn alpha helical segment at the N terminus of hbeta2 prevents the surface expression of hbeta2, that is, the helical segment itself is a retention signal. Using the c-Myc epitope-tagged extracellular loop of hbeta2, we reveal that the most accessible site by antibody is located at the middle of the extracellular loop, which might provide clues to understand how the auxiliary beta subunits regulates the toxin sensitivity and the rectification of BK-type channels.

Providing a Calcium Source

Gliomas--highly migratory brain malignancies derived from glia--express an unusual splice variant of BK channels (large conductance potassium channels independently activated by depolarization and calcium) whose activity may support migration of these diffusely infiltrating tumors. Noting that gliomas are not excitable and that global increases in intracellular calcium concentration ([Ca 2+ ] i ) of sufficient magnitude to activate BK channels would be expected to influence numerous other Ca 2+ -dependent processes, Weaver et al . investigated the possibility that activation of glioma BK channels might depend on a nearby Ca 2+ source. Immunofluorescence analysis of two glioma cell lines revealed that BK channels localized with lipid raft markers in "hot spots" at the protruding edges of cells. Furthermore, Western analysis of fractionated cell lysates indicated that BK channels were associated with a lipid raft fraction defined by the presence of caveolin-1. Treatment of U251 cells with methyl-β-cyclodextrin to disrupt lipid rafts led to BK channel redistribution and rapidly decreased whole-cell BK currents. This reduction in BK current was not associated with channel internalization, nor was it associated with a loss of BK channel sensitivity to a global increase in [Ca 2+ ] i . Pharmacological analysis indicated that inositol 1,4,5-trisphosphate receptors (IP 3 Rs), which were present in BK-containing hot spots and lipid raft fractions but did not coimmunoprecipitate with BK channels, provided the calcium source for BK activation. Thus, the authors propose that the localization of BK channels to lipid rafts allows IP 3 -mediated signaling pathways to activate BK channels and suggest that disruption of such pathways may provide a novel approach to inhibiting glioma migration. A. K. Weaver, M. L. Olsen, M. B. McFerrin, H. Sontheimer, BK channels are linked to inositol 1,4,5-triphosphate receptors via lipid rafts. J. Biol. Chem. 282 , 31558-31568 (2007). [Abstract] [Full Text]

Functional and Molecular Evidence for Impairment of Calcium-Activated Potassium Channels in Type-1 Diabetic Cerebral Artery Smooth Muscle Cells

Cerebral vascular dysfunction and associated diseases often occur in type-1 diabetes, but the underlying mechanisms are largely unknown. In this study, we sought to determine whether big-conductance, Ca(2+)-activated K(+) (BK) channels were impaired in vascular (cerebral artery) smooth muscle cells (CASMCs) from streptozotocin-induced type-1 diabetic mice using patch clamp, molecular biologic, and genetic approaches. Our data indicate that the frequency and amplitude of spontaneous transient outward currents (STOCs) are significantly decreased, whereas the activity of spontaneous Ca(2+) sparks is increased, in diabetic CASMCs. The sensitivity of BK channels to voltage, Ca(2+), and the specific inhibitor iberiotoxin are all reduced in diabetic myocytes. Diabetic mice show increased myogenic tone and decreased contraction in response to iberiotoxin in cerebral arteries and elevated blood pressure. The expression of the BK channel beta1, but not alpha-subunit protein, is markedly decreased in diabetic cerebral arteries. Diabetic impairment of BK channel activity is lost in CASMCs from BK channel beta1-subunit gene deletion mice. In conclusion, the BK channel beta1-subunit is impaired in type-1 diabetic vascular SMCs, resulting in increased vasoconstriction and elevated blood pressure, thereby contributing to vascular diseases in type-1 diabetes.

Diabetes Downregulates Large-Conductance Ca 2+ -Activated Potassium β1 Channel Subunit in Retinal Arteriolar Smooth Muscle

Retinal vasoconstriction and reduced retinal blood flow precede the onset of diabetic retinopathy. The pathophysiological mechanisms that underlie increased retinal arteriolar tone during diabetes remain unclear. Normally, local Ca(2+) release events (Ca(2+)-sparks), trigger the activation of large-conductance Ca(2+)-activated K(+)(BK)-channels which hyperpolarize and relax vascular smooth muscle cells, thereby causing vasodilatation. In the present study, we examined BK channel function in retinal vascular smooth muscle cells from streptozotocin-induced diabetic rats. The BK channel inhibitor, Penitrem A, constricted nondiabetic retinal arterioles (pressurized to 70mmHg) by 28%. The BK current evoked by caffeine was dramatically reduced in retinal arterioles from diabetic animals even though caffeine-evoked [Ca(2+)](i) release was unaffected. Spontaneous BK currents were smaller in diabetic cells, but the amplitude of Ca(2+)-sparks was larger. The amplitudes of BK currents elicited by depolarizing voltage steps were similar in control and diabetic arterioles and mRNA expression of the pore-forming BKalpha subunit was unchanged. The Ca(2+)-sensitivity of single BK channels from diabetic retinal vascular smooth muscle cells was markedly reduced. The BKbeta1 subunit confers Ca(2+)-sensitivity to BK channel complexes and both transcript and protein levels for BKbeta1 were appreciably lower in diabetic retinal arterioles. The mean open times and the sensitivity of BK channels to tamoxifen were decreased in diabetic cells, consistent with a downregulation of BKbeta1 subunits. The potency of blockade by Pen A was lower for BK channels from diabetic animals. Thus, changes in the molecular composition of BK channels could account for retinal hypoperfusion in early diabetes, an idea having wider implications for the pathogenesis of diabetic hypertension.

Tuning Magnesium Sensitivity of BK Channels by Mutations

Intracellular Mg2+ at physiological concentrations activates mSlo1 BK channels by binding to a metal-binding site in the cytosolic domain. Previous studies suggest that residues E374, Q397, and E399 are important in Mg2+ binding. In the present study, we show that mutations of E374 or E399 to other amino acids, except for Asp, abolish Mg2+ sensitivity. These results further support that the side chains of E374 and E399 are essential for Mg2+ coordination. To the contrary, none of the Q397 mutations abolishes Mg2+ sensitivity, suggesting that its side chain may not coordinate to Mg2+. However, because Q397 is spatially close to E374 and E399, its mutations affect the Mg2+ sensitivity of channel gating by either reducing or increasing the Mg2+ binding affinity. The pattern of mutational effects and the effect of chemical modification of Q397C indicate that Q397 is involved in the Mg2+-dependent activation of BK channels and that mutations of Q397 alter Mg2+ sensitivity by affecting the conformation of the Mg2+ binding site as well as by electrostatic interactions with the bound Mg2+ ion.

Downregulation of the BK channel beta1 subunit in genetic hypertension.

The molecular mechanisms underlying increased arterial tone during hypertension are unclear. In vascular smooth muscle, localized Ca2+ release events through ryanodine-sensitive channels located in the sarcoplasmic reticulum (Ca2+ sparks) activate large-conductance, Ca2+-sensitive K+ (BK) channels. Ca2+ sparks and BK channels provide a negative feedback mechanism that hyperpolarizes smooth muscle and thereby opposes vasoconstriction. In this study, we examined Ca2+ sparks and BK channel function in Wistar-Kyoto (WKY) rats with borderline hypertension and in spontaneously hypertensive rats (SHR), a widely used genetic model of severe hypertension. We found that the amplitude of spontaneous BK currents in WKY and SHR cells were smaller than in normotensive cells even though Ca2+ sparks were of similar magnitude. BK channels in WKY and SHR cells were less sensitive to physiological changes in intracellular Ca2+ than normotensive cells. Our data indicate that decreased expression of the BK channel beta1 subunit underlies the lower Ca2+ sensitivity of BK channels in SHR and WKY myocytes. We conclude that the lower expression of the beta1 subunit during genetic borderline and severe hypertension reduced BK channel activity by decreasing the sensitivity of these channels to physiological changes in Ca2+. These results support the view that changes in the molecular composition of BK channels may be a fundamental event contributing to the development of vascular dysfunction during hypertension.

Coupling strength between localized Ca(2+) transients and K(+) channels is regulated by protein kinase C.

Localized Ca(2+) transients resulting from inositol trisphosphate (IP(3))-dependent Ca(2+) release couple to spontaneous transient outward currents (STOCs) in murine colonic myocytes. Confocal microscopy and whole cell patch-clamp techniques were used to investigate coupling between localized Ca(2+) transients and STOCs. Colonic myocytes were loaded with fluo 3. Reduction in external Ca(2+) ([Ca(2+)](o)) reduced localized Ca(2+) transients but increased STOC amplitude and frequency. Simultaneous recordings of Ca(2+) transients and STOCs showed increased coupling strength between Ca(2+) transients and STOCs when [Ca(2+)](o) was reduced. Gd(3+) (10 microM) did not affect Ca(2+) transients but increased STOC amplitude and frequency. Similarly, an inhibitor of Ca(2+) influx, 1-2-(4-methoxyphenyl)-2-[3-(4-methoxyphenyl)propoxy]ethyl-1H-imidazole (SKF-96365), increased STOC amplitude and frequency. A protein kinase C (PKC) inhibitor, GF-109203X, also increased the amplitude and frequency of STOCs but had no effect on Ca(2+) transients. Phorbol 12-myristate 13-acetate (1 microM) reduced STOC amplitude and frequency but did not affect Ca(2+) transients. 4alpha-Phorbol (1 microM) had no effect on STOCs or Ca(2+) transients. Single channel studies indicated that large-conductance Ca(2+)-activated K(+) (BK) channels were inhibited by a Ca(2+)-dependent PKC. In summary 1) Ca(2+) release from IP(3) receptor-operated stores activates Ca(2+)-activated K(+) channels; 2) Ca(2+) influx through nonselective cation channels facilitates activation of PKC; and 3) PKC reduces the Ca(2+) sensitivity of BK channels, reducing the coupling strength between localized Ca(2+) transients and BK channels.

Dihydroxyeicosatrienoic acids are potent activators of Ca(2+)-activated K(+) channels in isolated rat coronary arterial myocytes.

1. Dihydroxyeicosatrienoic acids (DHETs), which are metabolites of arachidonic acid (AA) and epoxyeicosatrienoic acids (EETs), have been identified as highly potent endogenous vasodilators, but the mechanisms by which DHETs induce relaxation of vascular smooth muscle are unknown. Using inside-out patch clamp techniques, we examined the effects of DHETs on the large conductance Ca(2+)-activated K(+) (BK) channels in smooth muscle cells from rat small coronary arteries (150-300 microM diameter). 2. 11,12-DHET potently activated BK channels with an EC(50) of 1.87 +/- 0.57 nM (n = 5). Moreover, the three other regioisomers 5,6-, 8,9- and 14,15-DHET were equipotent with 11,12-DHET in activating BK channels. The efficacy of 11,12-DHET in opening BK channels was much greater than that of its immediate precursor 11,12-EET. In contrast, AA did not significantly affect BK channel activity. 3. The voltage dependence of BK channels was dramatically modulated by 11,12-DHET. With physiological concentrations of cytoplasmic Ca(2+) (200 nM), the voltage at which the channel open probability was half-maximal (V(1/2)) was shifted from a baseline of 115.6 +/- 6.5 mV to 95.0 +/- 10.1 mV with 5 nM 11,12-DHET, and to 60.0 +/- 8.4 mV with 50 nM 11,12-DHET. 4. 11,12-DHET also enhanced the sensitivity of BK channels to Ca(2+) but did not activate the channels in the absence of Ca(2+). 11,12-DHET (50 nM) reduced the Ca(2+) EC(50) of BK channels from a baseline of 1.02 +/- 0.07 microM to 0.42 +/- 0.11 microM. 5. Single channel kinetic analysis indicated that 11,12-DHET did not alter BK channel conductance but did reduce the first latency of BK channel openings in response to a voltage step. 11,12-DHET dose-dependently increased the open dwell times, abbreviated the closed dwell times, and decreased the transition rates from open to closed states. 6. We conclude that DHETs hyperpolarize vascular smooth muscle cells through modulation of the BK channel gating behaviour, and by enhancing the channel sensitivities to Ca(2+) and voltage. Hence, like EETs, DHETs may function as endothelium-derived hyperpolarizing factors.

Vasoregulation by the beta1 subunit of the calcium-activated potassium channel.

Small arteries exhibit tone, a partially contracted state that is an important determinant of blood pressure. In arterial smooth muscle cells, intracellular calcium paradoxically controls both contraction and relaxation. The mechanisms by which calcium can differentially regulate diverse physiological responses within a single cell remain unresolved. Calcium-dependent relaxation is mediated by local calcium release from the sarcoplasmic reticulum. These 'calcium sparks' activate calcium-dependent potassium (BK) channels comprised of alpha and beta1 subunits. Here we show that targeted deletion of the gene for the beta1 subunit leads to a decrease in the calcium sensitivity of BK channels, a reduction in functional coupling of calcium sparks to BK channel activation, and increases in arterial tone and blood pressure. The beta1 subunit of the BK channel, by tuning the channel's calcium sensitivity, is a key molecular component in translating calcium signals to the central physiological function of vasoregulation.

RINm5f cells express inactivating BK channels whereas HIT cells express noninactivating BK channels.

Large-conductance Ca2+- and voltage-activated BK-type K+ channels are expressed abundantly in normal rat pancreatic islet cells and in the clonal rat insulinoma tumor (RINm5f) and hamster insulinoma tumor (HIT) beta cell lines. Previous work has suggested that the Ca2+ sensitivity of BK channels in RIN cells is substantially less than that in HIT cells, perhaps contributing to differences between the cell lines in responsiveness to glucose in mediating insulin secretion. In both RIN cells and normal pancreatic beta cells, BK channels are thought to play a limited role in responses of beta cells to secretagogues and in the electrical activity of beta cells. Here we examine in detail the properties of BK channels in RIN and HIT cells using inside-out patches and whole cell recordings. BK channels in RIN cells exhibit rapid inactivation that results in an anomalous steady-state Ca2+ dependence of activation. In contrast, BK channels in HIT cells exhibit the more usual noninactivating behavior. When BK inactivation is taken into account, the Ca2+ and voltage dependence of activation of BK channels in RIN and HIT cells is essentially indistinguishable. The properties of BK channel inactivation in RIN cells are similar to those of inactivating BK channels (termed BKi channels) previously identified in rat chromaffin cells. Inactivation involves multiple, trypsin-sensitive cytosolic domains and exhibits a dependence on Ca2+ and voltage that appears to arise from coupling to channel activation. In addition, the rates of inactivation onset and recovery are similar to that of BKi channels in chromaffin cells. The charybdotoxin (CTX) sensitivity of BKi currents is somewhat less than that of the noninactivating BK variant. Action potential voltage-clamp waveforms indicate that BK current is activated only weakly by Ca2+ influx in RIN cells but more strongly activated in HIT cells even when Ca2+ current magnitude is comparable. Concentrations of CTX sufficient to block BKi current in RIN cells have no effect on action potential activity initiated by glucose or DC injection. Despite its abundant expression in RIN cells, BKi current appears to play little role in action potential activity initiated by glucose or DC injection in RIN cells, but BK current may play an important role in action potential repolarization in HIT cells.

Ca2+ sensitivity of BK channels in GH3 cells involves cytosolic phospholipase A2.

To test the hypothesis that intracellular Ca2+ activation of large-conductance Ca2+-activated K+ (BK) channels involves the cytosolic form of phospholipase A2 (cPLA2), we first inhibited the expression of cPLA2 by treating GH3 cells with antisense oligonucleotides directed at the two possible translation start sites on cPLA2. Western blot analysis and a biochemical assay of cPLA2 activity showed marked inhibition of the expression of cPLA2 in antisense-treated cells. We then examined the effects of intracellular Ca2+ concentration ([Ca2+]i) on single BK channels from these cells. Open channel probability (Po) for the cells exposed to cPLA2 antisense oligonucleotides in 0.1 microM intracellular Ca2+ was significantly lower than in untreated or sense oligonucleotide-treated cells, but the voltage sensitivity did not change (measured as the slope of the Po-voltage relationship). In fact, a 1,000-fold increase in [Ca2+]i from 0.1 to 100 microM did not significantly increase Po in these cells, whereas BK channels from cells in the other treatment groups showed a normal Po-[Ca2+]i response. Finally, we examined the effect of exogenous arachidonic acid on the Po of BK channels from antisense-treated cells. Although arachidonic acid did significantly increase Po, it did so without restoring the [Ca2+]i sensitivity observed in untreated cells. We conclude that although [Ca2+]i does impart some basal activity to BK channels in GH3 cells, the steep Po-[Ca2+]i relationship that is characteristic of these channels involves cPLA2.

Role of Ca(2+)-activated K+ channels in electrical activity of longitudinal and circular muscle layers of canine colon

The role of Ca(2+)-activated K+ channels (BK channels) in the canine colon was evaluated by testing the effects of charybdotoxin (ChTX) and tetraethylammonium on K+ currents of isolated myocytes and on electrical and mechanical activity of tissue strips. ChTX blocked Ca(2+)-activated outward current [IK(Ca)] in a dose- and voltage-dependent manner. No significant differences in IK(Ca) density, ChTX block, or Ca2+ sensitivity of BK channels were observed between circular and longitudinal myocytes. ChTX (100 nM) blocked 60% of current at +80 mV. Delayed rectifier current was not inhibited by 100 nM ChTX. In the absence of agonists, ChTX did not affect electrical or mechanical activity of circular muscle strips. In the presence of 10(-6) M BAY K 8644 or 10(-6) M acetylcholine, ChTX increased slow-wave duration and amplitude, induced membrane potential oscillations, and potentiated contraction. In unstimulated longitudinal muscle strips, ChTX depolarized the tissue, increased burst duration and spiking frequency, and resulted in an increase in contractions. These results indicate that BK channels are important regulators of colonic motility. In the longitudinal layer, BK channels are involved in setting membrane potential and determine excitability. In the circular layer, ChTX-sensitive channels do not participate in the in vitro basal electrical activity but limit the responses to excitatory agonists.

Properties of large-conductance K+ channels in human myometrium during pregnancy and labour.

The conversion of the electrically silent pregnant uterus to highly excitable at term represents a dramatic physiological event which is poorly understood. Here we provide the first description, from single-channel recordings, of a large conductance (212 pS) calcium-activated potassium channel (BKCa) in human pregnant myometrium which, in labour tissue, is either absent or has been considerably altered in its physiological and pharmacological properties. In the latter, the K+ channels have an identical conductance (221 pS) and K+ selectivity to BKCa channels but exhibit no Ca2+ or voltage sensitivity. We have termed these BK channels. Furthermore, the activity of the BKCa channel from pregnant tissue is inhibited by internal application of Ba2+ but not tetraethylammonium (TEA), whereas the activity of the BK channel is sensitive to internal TEA but not Ba2+. The role of the BKCa channel may be to suppress myometrial activity during gestation whereas BK channel activity may be important in providing a Ca(2+)-independent K+ conductance which would allow cytoplasmic Ca2+ levels to rise without activating a counteracting Ca(2+)-dependent outward current, normally provided by the BKCa channels which, by its very nature, would tend to oppose depolarization. The findings suggest that K+ channels may have an important role in determining the functional activity of the myometrium.