Cultured melanotrophs of the adult rat pituitary possess a voltage-activated fast transient outward current

Eicosatetraynoic acid (ETYA), a non-metabolizable analogue of arachidonic acid, blocks the fast-inactivating potassium current of rat pituitary melanotrophs

The effects of arachidonic acid (5,8,11,14-eicosatetraenoic acid, AA) and 5,8,11,14-eicosatetraynoic acid (ETYA), a non-metabolizable analogue of AA, were examined on the transient [IK(f)] and the delayed rectifier-like [IK(s)] voltage-gated potassium currents in rat pituitary melanotrophs. The main questions addressed were whether AA and ETYA blocked IK(f) and if any blocking action was specific. Macroscopic currents were measured using the patch clamp technique. Bath application of 20 µM AA reduced IK(f), however, the degree of the block varied between cells. In contrast, ETYA consistently inhibited IK(f). Fitting of the charge transfer or the peak current amplitude yielded KD estimates for ETYA of 1.2 µM and 3.3 µM, respectively. The reduction by ETYA of peak IK(f) was always associated with an increased rate of current decay, but there was no detectable change of the kinetics of activation. ETYA caused a small left shift of the IK(f) steady-state inactivation curve and significantly slowed recovery from inactivation. At 20 µM, ETYA also reduced IK(s), indicating that it is not specific. The possibility that ETYA acts as an open-channel blocker is discussed.Key words: transient potassium current, melanotroph, eicosatetraynoic acid, ETYA, arachidonic acid.

Changes of activation and inactivation gating of the transient potassium current of rat pituitary melanotrophs caused by micromolar Cd2+ and Zn2+

We studied the effects of Zn2+ and Cd2+ on the behaviour of IK(f), a transient outward potassium current in acutely dissociated melanotrophs of the pars intermedia of the rat pituitary gland. Micromolar concentrations of external Cd2+ or Zn2+ caused parallel and nearly equal rightward shifts along the voltage axis of the activation and steady-state inactivation curves for IK(f). The KD for the half-maximal shift of the activation curve was 278 microM for Cd2+ and 93 microM for Zn2+; the maximal shifts of the activation curve were 32.5 and 34 mV, for Cd2+ and Zn2+, respectively. The times to half-activation and half-inactivation were shifted rightward by 30-60 mV in both 500 microM Cd2+ and 500 microM Zn2+. We suggest that Cd2+ and Zn2+ interact specifically with a binding site on or electrically close to the IK(f) channel and in so doing modify the electric field "seen" by the voltage sensors.

Block by capsaicin of voltage-gated K+ currents in melanotrophs of the rat pituitary

1. Whole-cell recordings of macroscopic K+ currents were made from acutely dissociated and cultured melanotrophs isolated from the pars intermedia of the adult rat pituitary. 2. In acutely dissociated cells, external capsaicin reversibly decreased the amplitude both of the fast-activating, fast-inactivating potassium current IK(f) and the slowly-activating, slowly-inactivating potassium current IK(s). To simplify the investigation of the mechanism of action of capsaicin experiments were conducted on cultured melanotrophs that express only IK(s). 3. In control cells the activation rate and the amplitude of IK(s) increased with depolarization and the current showed very little inactivation at any voltage during pulses lasting for 100-300 ms. In capsaicin, the decrease of the current amplitude was associated with an increased rate of current decay ('inactivation'). At a given voltage, the extent and the rate of the capsaicin-induced inactivation was proportional to the capsaicin concentration; and, at a given concentration, the extent and rate of the inactivation increased with membrane depolarization. 4. The fit of the Hill equation to data derived from the steady-state block of IK(s) evoked at 10 mV indicated an equilibrium dissociation constant (KD) of 17.4 microM (95% confidence limits 15.8-19.0) and a Hill coefficient of 1.8 (95% Cl 1.5-2.2) suggesting that at least two molecules of capsaicin must bind to the channel to block it. 5. Analysis of the voltage-dependence of the steady-state block in 100 microM capsaicin showed that half-maximal block occurred at -29 +/- 2 mV (n = 10). Two-pulse experiments designed to study the time-dependence of channel block in 100 MicroM capsaicin indicated that the blocking kinetics were well fitted by a single exponential and that the rate of block increased with depolarization. The value for Tblock at 0mV was 24 +/-7ms (n=4).6. Recovery from block in 100 MicroM capsaicin was also well fitted by a single exponential. The recovery time constant ( was 708 +/- 140 ms at - 50 mV, 70 +/- 6 ms at - 70 mV and 19 +/- 1.3 ms at-90 mV (n = 4).7. In 50-100 MicroM capsaicin, the decay of the tail current was biexponential, the values for fast and Tslow being, respectively, less than and greater than the single time constant fitted to the control tail current.Inward and outward K+ currents were equally affected by capsaicin.8. Most of these effects of capsaicin on the IK(S) of melanotrophs can be accounted for by a kinetic scheme in which capsaicin binds to and blocks open K+ channels.

Voltage-clamp analysis of the voltage-gated sodium current of the rat pituitary melanotroph

By using the whole-cell recording technique the Na+ current in cultured melanotrophs of the adult rat pituitary was studied. The Na+ current was eliminated by 1 microM TTX and its equilibrium potential confirmed that it was carried predominantly by Na+. The activation threshold was near -40 mV and half-maximal activation occurred at approximately -23 mV. The peak amplitude of 640 +/- 110 pA (n = 8) occurred near -10 mV. Steady-state half-inactivation occurred near -50 mV. Recovery from inactivation at -70 mV was biexponential: approximately half of the channels recovered with a time constant of 13 ms whereas the slower phase of recovery had a time constant of 430 ms. These properties of the Na+ current are discussed in relation to its role in cell firing and hormone secretion.

Dopamine inhibits voltage-activated calcium channel currents in rat pars intermedia pituitary cells

Several lines of evidence suggest that dopamine acts as a neurotransmitter that inhibits both hormone secretion and electrical activity in pituitary intermediate cells (melanotrophs). In this study we examined the effects of exogenously applied dopamine on voltage activated calcium currents recorded with the whole-cell mode of the patch-clamp technique from short-term primary cultures of melanotrophs. Two types of calcium currents were distinguished by their voltage dependence and kinetics of inactivation similar to the low voltage-activated currents (LVA; or T-type) and high voltage-activated currents (HVA; N&L-types) of calcium currents. Exogenously applied dopamine (2-20 microM) reversibly reduced both LVA and HVA types of calcium currents. Evidence for these results came from experiments in which LVA and HVA calcium currents were separated by stepping to different membrane potentials from a fixed holding potential (Vh) or by changing Vh. These results suggest that dopamine can regulate the entry of calcium into melanotrophs by acting on at least two different populations of calcium channels thereby affecting hormone secretion and electrical activity.

Patch-clamp analysis of voltage-gated currents in intermediate lobe cells from rat pituitary thin slices

Ionic currents of hypophyseal intermediate lobe cells were studied using a thin-slice preparation of the rat pituitary in conjunction with conventional and perforated whole-cell patch-clamp recording techniques. A majority (89%) of the cells studied generated Na+, Ca2+ and K+ currents upon depolarizing voltage steps and responded to bath application of gamma-aminobutyric acid (GABA; 20-50 microM) with inward currents (in symmetrical chloride, holding potential -80 mV). A small percentage of cells (11%) did not display inward membrane currents upon depolarization and was unresponsive to GABA. In the first type of cells, Ca2+ and K+ currents were further studied in isolation. Ca2+ tail currents showed a biphasic time course upon repolarization, with time constants and amplitudes of 2.07 +/- 0.29 ms, 123 +/- 22 pA (for the slowly deactivating component) and 0.14 +/- 0.06 ms, 437 +/- 33 pA (for the fast-deactivating component; means +/- SD of n = 4 cells). Slowly and fast-deactivating conductances were half-maximally activated at around -10 mV and +10 mV respectively. Depolarizing voltage steps elicited two types of K+ current, which were separated using a prepulse protocol. A fast-activating, transient component showed half-maximal steady-state inactivation between -65 mV and -45 mV depending on the divalent cation composition of the external solution. Its decay was fitted by single-exponential functions with time constants of 36 +/- 11 ms and 3.9 +/- 0.9 ms at -20 mV and +40 mV respectively (mean +/- SD; n = 4 cells). Whereas the peak current amplitudes of the transient K+ current component remained stable, the amplitude of the second, delayed component increased progressively throughout the course of whole-cell experiments. In cells recorded with the perforated whole-cell technique, bath application of dopamine (10 nM-1 microM) induced large hyperpolarizations from a spontaneous membrane potential of -40 mV, but did not consistently affect the amplitude of the voltage-gated K+ conductances. These data are compared to previous studies using other preparations of the intermediate lobe, and differences are discussed, thus helping to extend our knowledge of electrical excitability of hypophyseal cells.

Quinidine-induced inhibition of the fast transient outward K+ current in rat melanotrophs

1. The effect of quinidine on the fast-activating, fast-inactivating potassium current (IK(f] in acutely dissociated melanotrophs of the adult rat pituitary was examined. Macroscopic currents were measured by use of the whole-cell configuration of the patch clamp technique. 2. Bath application of quinidine caused a dose-dependent reduction of the peak amplitude of IK(f). The Kd for blockade of IK(f) at 0 mV was estimated to be 41 +/- 5.6 microM. 3. Quinidine elicited a dose-dependent increase of the rate of the decay of IK(f) and this effect was enhanced by membrane depolarization. The possibility that this phenomenon reflects an open channel blocking reaction is discussed. 4. Quinidine also caused a 5 mV hyperpolarizing shift of the steady-state inactivation curve and increased the half-time for recovery from inactivation. Quinidine did not affect the onset of inactivation measured at -30 mV. 5. Internal quinidine did not appear substantially to affect either the peak amplitude or kinetics of IK(f). 6. A study of some structural analogues showed that hydroquinidine and quinacrine had effects similar to those of quinidine. The effect of quinacrine on the amplitude and kinetics of IK(f) was also pH-dependent. Cinchonine, which bears a close structural resemblance to quinidine, was much less effective as a blocker of IK(f).

Catechol blocks the fast outward potassium current in melanotrophs of the rat pituitary

The effect of catechol on the fast voltage-gated K+ current (IK(f)) of acutely dissociated rat melanotrophs was investigated in whole-cell recordings. Half-maximal inhibition of IK(f) occurred at an external concentration of 1.7 mM and this effect was associated with a decrease of the rate of the current decay. Internal catechol had no measurable effect on IK(f). Catechol appeared to be equally effective as a blocker of the slow voltage-gated K+ current (IK(s)). Despite this lack of specificity the blocking action of catechol was voltage- and frequency-independent and was rapidly reversible. Catechol therefore represents a useful alternative to 4-aminopyridine as a blocker of IK(f).

4-Aminopyridine causes a voltage-dependent block of the transient outward K+ current in rat melanotrophs

1. Whole-cell voltage-clamp recordings were made from acutely dissociated melanotrophs obtained from adult rats. 2. In the presence of external Na+ and Ca2+ channel blockers and 20 mM-tetraethylammonium (TEA) depolarizations to -40 mV or more evoked a fast-activating fast-inactivating outward K+ current (IK(f)). Double-pulse experiments showed that steady-state half-inactivation occurred near -37 mV; half-maximal activation of IK(f) occurred at -15 mV. Recovery from inactivation in most cells fitted a single exponential with a time constant of 40-50 ms. 3. When applied either internally or externally, 1-2.5 mM-4-aminopyridine (4-AP) substantially reduced IK(f) but the degree of block was affected by the intensity, duration and frequency of depolarizing commands. 4. Analysis of the steady-state voltage dependence of the block by 4-AP showed that half-maximal blocking occurred at approximately -31 mV. This implied that 4-AP binds to the resting state of the IK(f) channel. 5. Studies of the time dependence for the blocking or unblocking of IK(f) showed that both processes were exponential with mean time constants of 1942 ms (at -70 mV) and 726 ms (at 20 mV), respectively. Recovery from inactivation was apparently unaffected by 4-AP. 6. A four-state sequential model in which 4-AP reversibly binds to the resting state of the channel replicates the frequency dependence of the 4-AP blockade.